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DELIVERABLE 2.1 Pre-commercial procurement: Best practices and alternatives in the European eHealth sector
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PRECO PCP BEST PRACTICE CASES STUDY in the domain of eHEALTH
Main authors:
Suzan Ikävalko, Culminatum Innovation, Finland
Max Rolfstam, University of Southern Denmark (case studies)
Contents:
1. Document reference & Introduction 3
2. What is eHealth and why focus on eHealth 4
3. PCP & Innovation framework 6
4. PRECO BEST PRACTICE CASES in the field of eHealth; Comparative Case Chart 9
5. Policy Recommendations for advancing PCP in the field of eHealth 19
Appendixe 1: PRECO eHealth case descriptions 28
Appendixe 2: On alternative Public Demand systems and R&D procurement models 61
- Demand systems for innovation
- PPI
- User-Driven Innovation as a driver for PCP in the Health sector
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1. Document reference & Introduction
This document contributes to deliverables of the project called “Enhancing Innovation in Pre-commercial Public Purchasing Processes” (PreCo). The PreCo project is a FP7 coordination action funded by the European Commission DG INFSO. The overall objective of this coordination action is to support public authorities in undertaking pre-commercial procurement (PCP) actions that render innovation and citizen participations. In order to fulfil this purpose, the PreCo project established a thematic network for the development and adaptation of European wide models, frameworks and policy recommendations in two areas, eHealth and eEnergy. The ambition with the network was to bring together stakeholders from various parts of the public sector RDI process: Public authorities, supply side actors (eHealth industry actors), innovation agencies, Living Labs and universities. The network would enable benchmarking among partners best practices and policies, and joint development of guidelines for participative pre-commercial RDI activities. The PreCo project was organised in 4 Work Packages, with the following objectives: WP 1: To launch the network and conduct a preliminary assessment of current practices in relation to PCP in Europe. WP 2 and WP 3: Specific focus on two empirical thematic domains, the eHealth sector and the eEnergy sectors respectively, including identification of best practice cases in these domains. WP 4: To provide Policy Recommendations based on identified best practices, barriers and on other types of research conducted during the project. The PreCo project consists of ten partners from seven different countries: Culminatum Innovation Oy Ltd (FI) Alfamicro- Sistemas De Computadore S (Pt) EPMA- Agentura pro evropske projekty & management (Cz) Fundacion Comunidad Valenciana- Region Europea (ES) University of Southern Denmark (DK) Vysocina Kraj (Cz) Aalto University School of Economics (FI) Copenhagen Living Labs Aps (Dk), Amsterdam Innovation Motor (Nl) Unione Regionale Delle Camere Di Commercio Industria Artigianato E Agricoltura Del Veneto (IT)
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2. What is eHealth and Why focus on PCP in the Health and Assisted Living sectors What is meant with E-HEALTH?
eHealth means Information and Communication Technologies tools and services for health. Whether eHealth tools are used by healthcare professionals, or directly by patients or by both they play a significant role in improving the health of European citizens.
eHealth covers the interaction between patients and health-service providers, institution-to-institution transmission of data, or peer-to-peer communication between patients and/or health professionals. Examples include health information networks, electronic health records, telemedicine services, wearable and portable systems which communicate, health portals, and many other ICT-based tools assisting disease prevention, diagnosis, treatment, health monitoring and lifestyle management.
eHealth is an integral component of the EU’s Digital Agenda that focuses on ICTs capability to reduce energy consumption, support ageing citizens' lives, revolutionizes health services and deliver better public services.
The EU eHealth framework and recent developments:
Healthcare systems are becoming increasingly dependent on Information and Communication
Technologies (ICTs) to deliver top-quality care to European citizens. The EU’s eHealth action
plan sets out a clear road map for this sector.
Technology is advancing at a fast pace and changing the complexion of our daily lives. This applies
just as much to the healthcare services we receive as to our work or leisure activities. Rapid and
reliable ICTs have become a vital component of efficient and effective ‘health management
systems’ in Europe and their use in healthcare will grow strongly in the future.
Although ICTs have been revolutionizing the healthcare sector in recent years, the EU has found
that efforts across the continent have been fragmented and could benefit from improved cross-
border coordination. eHealth tools and services have been widely introduced, but too often health
authorities, hospitals, or doctors have chosen and implemented their own individual systems. If
these systems are able to communicate with each other, the potential benefits they can bring to
patients will increase significantly.
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At European level, this fragmentation is even more pronounced. In a Union where citizens
increasingly travel across borders, individuals should be able to find the highest quality services
and make use of them.
Lead Market Initiative – eHealth: The Lead Market Initiative (LMI) for Europe was launched by the European Commission following the EU’s 2006 Broad based innovation strategy. The Lead Market Initiative for Europe will foster the emergence of six lead markets of high economic and societal value one of them being eHealth. (It was chosen to be one of the six markets of the LMI initiative due to its market potential in terms of growing demand and market growth opportunities, changing demographics and disease patterns, and healthcare capabilities.)
In March 2011 European Commission launched a consultation on the eHealth Action Plan (eHAP) 2012-2020. This second eHealth action plan (eHAP) will provide an opportunity to consolidate the actions which have been addressed to date, take them a step further where possible and provide a longer term vision for eHealth in Europe, in the context the EU 2020 Strategy, the Digital Agenda for Europe as well as Innovation Union and its associated European Innovation Partnership on Active and Healthy Ageing.
The connection between PCP eHealth and wider EU eHealth developments:
EU Commission eHealth Action Plan (2012-2020)
In the EU Commission eHealth Action Plan focus is on the following challenges, which also include
some of the main barriers to PCP eHealth:
- Market fragmentation and lack of interoperability
- Lack of legal certainty
- Insufficient availability of financial support
- Procurement issues
Skills and knowledge gap most important:
On top of the challenges listed in the eHealth Action Plan there is also a clearly identified skills and
knowledge gap. Any attempt to secure investment and uptake of eHealth also through PCP has to
deal with these challenges as well
“Supporting and financing eHealth” -study: (http://www.financing-ehealth.eu/) states the
following:
“Identified skills and knowledge gap seems to be the most significant factor that impedes
progress”. “More widespread skills and knowledge in taking and delivering eHealth investment
decisions is more important than more finance”.
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Shortfalls in the real resources for eHealth include:
Significant lack of skills and capabilities to deal with all eHealth requirements
Limited view of the potential of eHealth by many healthcare professional, executives and managers, leading to narrowly defined eHealth investment plans.
While there are sources of financing individual eHealth projects, only limited financing
opportunities are available to fix above mentioned shortfalls and for integrated (long term)
strategic ehealth/healthcare investments. Recurring public budgets dedicated specifically to
eHealth are the exception (Austria, England, Spain)
Use PCP in order to acquire innovations and cohesion in the eHealth field and to stop the slow
cycle of decline of public healthcare services:
Pre-commercial public procurement could be used as a tool to address the above mentioned
challenges. Possibly also as a tool to address shortcomings in the uptake of eHealth solutions in
the public healthcare services as described in the European eHealth strategies (* European
progress report 2011). PCP can be used to make the eHealth markets move and catalyze
transformation in public healthcare and ambient assisted services (home/self/remote care). Focus
can be on two levels of innovation:
- Stand alone innovative solutions
- Innovative solutions in integrated care models (remodeling the health services)
3. PCP – a tool for acquiring innovations through co-creation
A. LEGAL FRAMEWORK
Although studies show that the legal framework is not an obstacle in itself for innovative public procurement or PCP, it is often perceived like that. EU-legislation is providing the framework for public procurement, but there seem to be different national interpretations. In addition, there is a clear need to clarify the rules and to inform procurers about existing possibilities provided by innovative new practices such as PCP, which do not fall under the EU procurement law. A key to a successful innovative public procurement process is an understanding of the possibilities the existing legal framework provides.
• General procurement legislation (EU & national, the latter being in most cases directly
compatible with the EU legislation). Competitive dialogue often used for more complex
procurements with innovative aspects.
• Art 16 F(exemption)
Public authorities can buy innovation without commitment to the procurement directives
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PCP ( COM 2007:799 final)
Briefly, pre-commercial procurement is characterized by following three aspects:
Risk-benefit sharing according to market conditions
Competitive development in phases
Separation of the R&D phase from deployment of commercial products Pre-commercial procurement gives an opportunity to develop different ideas in parallel where one, or few
of the initial ideas (solution specifications) will ideally eventually be selected for commercial public
procurement in accordance with the Procurement Directives.
Basic challenges/risks connected to PCP approach
• No automatic purchase/commercialization of the developed product/service
• The risk of supplier exclusion
• The fear of illegal state aid
The typical public procurement officer: Conservative, risk reluctant , bound by silo/yearly budgets, afraid
of doing mistakes and showing ”not knowing” , afraid and restricted in action by unclear legal and
organizational frameworks , not supported by right incentives/resources, not having adequate and
sufficient knowledge and training for PCP or other new types of collaboratice innovation/procurement
processes. Consequences -> minimal innovation
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B. PCP & INNOVATION FRAMEWORK
Embed innovation into public procurement practices and service strategies
Renewal of the healthcare delivery and procurement systems - To modernise the health sector we need
to integrate innovation and procurement in a better way.
• There is a strong need for a quality and outcome wise better and more efficient health sector,
introductions of ICT based solutions being one way to deliver this.
• There is a generally stronger priority of innovation and demand & user led innovation processes
making use of the konowhow existing on the market and within the companies (supply side)
• Within the ICT area there is a rapid innovation development - early need based interction between
demand and supply side can further accelarate the development and deployment of ICT base
innovations.
• Market fragmentation needs to be addressed: Focus on joint needs assesment, interoperability,
open standadrs and scalable solutions while targeting market cohesion and sustainable business.
• Stop buying yesterdays products and services again and again.
PCP in summary: “FORWARD LOOKING COMMITMENT MATCHING THE PUBLIC NEEDS WITH SUPPLY SIDE
INNOVATION POTENTIAL IN AN EARLY R&D&I INVESTMENT/ CO-CREATION APPROACH”. As opposed to
paying for non-innovative solutions and likely shortcomings in the post-commercial procurement phase
C. PROCESS AND DIALOGUE
A successful innovative procurement depends on having a process that, besides fulfilling the legal
requirements, is appropriate in terms of identification of needs, dialogue and contractual procedures with
companies and relevant incentives for all parties etc. PCP clearly requires multidisciplinary competencies
and a structured, transparent and result oriented process approach. Most European contracting authorities
are currently not capable of embarking on PCP activities on their own, while the necessary competencies
are lacking. Facilitating organizations such as Innovation agencies, consultancies and competence centers
are therefore needed in the process.
D. INCENTIVES for PCP
Currently incentives for going for something else than a low cost or regular procurement practices are
weak. From procurer’s point of view, Incentives needed, can be found in categories such as:
Mandate: Policy/political, financial, strategy & managerial support
Means: allocation of resources (time & money), practical support & training etc.
Organizational structures: Ownership &leadership issues, new incentives etc
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For the suppliers incentives include: access to understanding of public sector needs and real life testing
environments, sound business case, rapid R&D cycle, structured result oriented process, commercial
procurement/ deployment of the innovation, wider diffusion. In other words having the possibility and
ability to work with potential clients on their needs in a structural way, making it more likely that R&D will
lead to commercial demand.
4. PRECO BEST PRACTICE CASES in the field of eHealth
PCP best practice cases are scarce within the European Union Member states. The cases collected and
analysed during the Preco project are therefore not pure PCP cases as defined by the EU PCP framework
and fall legally and process wise in different categories. as shown in the Case study chart. However, they do
contain caracteristics similar to the PCP process and serve to highlight some key aspect to be considered
when preparing a future PCP project. The aspects/factors are listed and described in the (best practice)
Case comparison chart below.
General Preco eHealth conclusions:
Based on the evidence acquired it seems clear that there is an identified need for a systematic tool for demand led public-private R&D&I processes. The tool should focus on the different phases and aspects of the process in line with those of the EU Commission PCP process. Subsequently one could argue that a PCP process could have worked better and provided better results for all parties in several of the analysed Preco cases as in comparison to the collaboration method chosen (in many cases a more loose Public Private Innovation process, based on Article 16 f ) .
The identified needs include e.g.:
A thorough early needs assessment including all key parties (companies, end-users etc)
Clear contractual and legal procedures, including risk management and the IPR’s (ownership & exploitation rights)
Formal commitments and roles of the parties involved in the process
Focus also on the commercialization phase, i.e. in securing deployment (through commercial procurement or wider diffusion) of the new solution/service as a final step in the Innovation chain.
The general findings indicate that different PPI models can be used for public-private collaboration and for creating innovations. However, their weakness is often: - No formalized, structured and professionally driven process - Lack of competition and envisaged deployment targets, making it uncertain whether the best and most innovative and cost/efficient solutions were created. - No financial compensation for the R&D phase - No deployment & commercialization & diffusion of the developed innovation The two latter factors also mean that the “business case” is lacking and this is something that many SMEs cannot afford. Even many bigger companies are discouraged by the fact that the public-private R&D processes they have been involved in have not resulted in anything “tangible”. Future PCP models and applications should therefore take these factors into account.
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In all PreCo cases we see that the R&D / procurement process in itself needs extra resources when the
process is more innovative. This is why pooling of demand and effective dissemination of knowledge &
results on a local level is very important. Otherwise every organization will start its own learning processes,
which will lead to extra costs and possibly dissatisfied contracting authorities and companies alike.
The cases included in this Preco report are listed in this table:
Case Description Location
Electronic Registration of Patients Jihlava Hospital, Vysočina Region, Czech Republic
The hospital bed of the future Region Midt, Denmark
The patient briefcase Silkeborg and Odense, Denmark
HealthLab Tsaar Peter and sensor technology Amsterdam, The Netherlands
Welfare-technology neighbourhood: robotic vacuum cleaner and the electronic keys
Copenhagen, Denmark
Radiotherapy appliances Bolzano Province, Italy
Stabilising splints for Fractured Neck of Femur NHS, United Kingdom
Healthy Helsinki Living Lab mHealth case Helsinki, Finland
CASE COMPARISON CHART
Case category A = following PCP, Case category B = following Article 16 f Case category C = GPL (General
Procurement Law)
Formal caracteristics A) PCP B) Article 16 f C)GPL REPRESENTATIVE
PRECO CASE
Regulatory framework/ Legal
base , applies to
Procurement of R
& D service
Procurement
of R&D
service
Any
commercial
procurement,
often
Competitive
Dialogue in
more
complex
product-
service cases
Case category A:
*Radiotherapy
appliances, Bolzano
*eAmbulance
*Stabilizing splints,
NHS/NIC
Case category B:
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*Welfare-
technology
neighbourhood
Case category C:
*The hospital bed
of the future
*The patient
briefcase, DK
Demand & user led exploratory
phase
Structured joint
needs assesment
leading to PCP
contact
specifications
Not
established,
differs
Case category A:
*Radiotherapy
appliances, Bolzano
*eAmbulance
*Stablising splints,
NHS/NIC
* Tsaar Peter,
Amsterdam
*The patient
briefcase, DK
Case category B:
*The hospital bed
of the future
*Welfare-
technology
neighbourhood
Award procedure Participants
found via PCP
tender
No
requirement
for tendering
Competitive
dialog
Case category A:
*Radiotherapy
appliances, Bolzano
*Stablising splints,
NHS/NIC
Case category B:
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*eAmbulance
*Helsinki mHealth
case
*Welfare-
technology
neighbourhood
*The patient
briefcase, DK
Case category C:
*The hospital bed
of the future
Financing of the R&D phase Financial
compensation by
CA (or other
funding body)
No
requirement,
practices
vary
Case category A:
*Hospital bed of
the future
*Tsaar Peter,
Amsterdam
*Stablising splints,
NHS/NIC
*The patient
briefcase, DK (only
some funding from
the CA)
Case category B:
*eAmbulance
*Helsinki mHealth
case
*Welfare-
technology
neighbourhood
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Number of companies Contract must be
awarded to
multiple
companies
No
requirement
Case category A:
*Hospital bed of
the future
*Stabilising splints,
NHS/NIC
Cas e category B:
*eAmbulance
*Helsinki mHealth
case
*The hospital bed
of the future
*Welfare-
technology
neighbourhood
Selection of companies Transparent &
non-
discriminatory
No
requirement.
local or well
known big
companies
often
prioritized.
Case category A:
*The hospital bed
of the future
*Stabilising splints,
NHS/NIC
*Tsaar Peter,
Amsterdam
Case category B:
*Radiotherapy
appliances, Bolzano
(PCP call only in
Italian&German
language),
*Helsinki mHealth
case
*Welfare-
technology
neighbourhood
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Midway evaluations The process
requires multiple
phases with
evaluation at the
end of each
phase to
eliminate one or
more companies
No
requirement,
the same
company can
develop from
start to finish
Case category A:
*Stablising splints,
NHS/NIC
*The patient
briefcase, DK
(multiple phases,
but only one
company)
Case category B:
*Helsinki mHealth
case
*Welfare-
technology
neighbourhood
*The hospital bed
of the future
IPR IPRs are shared.
Exploitation and
ownership rights
can be separeted.
CA can sell the
rights to a new
supplier in the
commercial
procurement
phase
IPRs not
retained
exclusively
by the
procuring
authority.
They can be
shared with
othe supplier
or public
authorities or
published.
Case category A:
*Stabilising splints,
NHS/NIC
Case category B:
*Welfare-
technology
neighbourhood
*The hospital bed
of the future
General caracteristics
Risk management1 Contractual and
structured
process based
risk management
Often not
formalized
Case category A:
*Welfare-
technology
neighbourhood
*The hospital bed
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of the future
*Stabilising splints,
NHS/NIC
Case category B:
Helsinki mHealth
case
*Tsaar Peter,
Amsterdam
End-user involvement / Living
Labs
Can be used, no
formal
requirements
IDEM Cases:
*Welfare-
technology
neighbourhood
*The hospital bed
of the future
*Stabilising splints,
NHS/NIC
*Tsaar Peter,
Amsterdam
*The patient
briefcase, DK
*Helsinki mHealth
case
Open Innovation, consortium as
supplier in the R&D phase2
Cases
*The hospital bed
of the future
*Tsaar Peter,
Amsterdam
Availability of real life testing
environment even in the
prototype phase
An interesting
incentive, nor
formal
requirements in
the process for
this
IDEM Cases:
*Welfare-
technology
neighbourhood
*The hospital bed
of the future
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*Stabilising splints,
NHS/NIC
*Tsaar Peter,
Amsterdam
*The patient
briefcase, DK
*Helsinki mHealth
case
Deployment /
Commercialization
Succesfull project
will ideally aim at
commercial
procurement by
the CA or
commercializaion
in other markets
Process
structure or
objectives
seldom
contain
explicitly this
aim.
Case category A:
*The hospital bed
of the future
*Stabilising splints,
NHS/NIC
*Tsaar Peter,
Amsterdam
Case category B:
Helsinki mHealth
case
*Welfare-
technology
neighbourhood
Driver for the R&D&I project
Innovation/procurement/service
strategy behind the R&D
investment
*The hospital bed
of the future
*Welfare-
technology
neighbourhood
*Stabilising splints,
NHS/NIC
Managerial or Lead-user
initiative within the CA
*The hospital bed
of the future
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*Welfare-
technology
neighbourhood
*Stabilising splints,
NHS/NIC
*The patient
briefcase, DK
Cost/benefit analysis based
understanding pushing for
renewal
*The hospital bed
of the future
*Welfare-
technology
neighbourhood
1RISK MANAGEMENT / ASSESMENT
• The potencial must be seen in the light of the gains. Investing in the PCP phase means de-risking
while;
- Significant post-commercial procurement adjustments often imply additional worktime and
financial investments which are not included in the original procurement budjet and thus not
even considered in the procurement and selection process
- The procured solution is likely to be of higher quality and better real needs adopted from the
start, than when acquired traditionally and only through commercial procurement .
- The solution is likely to to fit the service environment more rapidly , fluently and in a more
secure manner (also reduced technology risk). This implies also e.g. better user-acceptance,
fluency of clinician work, better patient satisfaction and patient security (less error in the care
delivery).
- Risk of bying yesterdays product diminished
- Pooling of demand diminshes the risk carried by single procurer / contracting authority (needs
are similar EU-wide, no need for each procurer to “invent the wheel over and over again”)
- PCP should be seen as an investment in a learning process where public sector capabilities are
strengtheded delivering gains even in future.
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PCP process can naturally also materialize risks such as a situation where PCP has lead to very customized
non-scalable products without commercial procurement by the PCP Contracting Authority. (However, even
in this case the supplier has been paid for the R&D).
2COMPETITION FRAMEWORK / OPEN INNOVATION / IPR management
The EU Commision recommends:
- a strict approach based om equal treatment and transparency
- a competition framework
However, a more flexible case by case adopted approach can be advisable. This could allow for consortium
building and for a flexible result oriented IPR management during the PCP process. Market stimulation
measures can be needed in order to attract new and even the smaller innovative companies. There is a
clear need to study further and engage also the companies (both big ones and the SMEs) in the future work
around issues such as Competition , Open innovation and IPR management. The feasability of different
practices in different specific thematic fields and cases can only be understood properly through connecting
the real actors and “owners” of the issues to be solved into shaping of these new practices – i.e. practical
understanding and evidence is needed both from the demand anf the supply side.
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5. Policy Recommendations for advancing PCP in the field of eHealth
Successful pre-commercial procurement action in the field of eHealth is dependent on several policy and
practical level developments taking place simultaneously both on EU level and on Member States level. The
need for adoption and implementation of different measures depends among others of the specifics of the
markets in question, e.g. national supply and demand side structures and support mechanisms for PCP
eHealth already in place.
Some of the Preco recommendations link directly also to the contents of the following EU reports:
* eHealth strategies – European progress report 2011
(http://ehealthstrategies.eu/report/eHealth_Strategies_Final_Report_Web.pdf)
* Final report on the public consultation on the eHealth Action Plan 2012-2020.
* Financing eHealth report ( www.financing-ehealth.eu )
Six policy recommendations facilitating eHealth uptake, applicable also for PCP eHealth:
1. Promote eHealth as a resource in healthcare and services, not as an end in itself
2. Focus on improving several aspects of health services, not on cash savings
3. Facilitate effective, comprehensive financing packages covering the whole investment
lifecycle, including long-term, recurring expenditure
4. Invest in more evidence on investment risks
5. Promote and facilitate stakeholder engagement, not just consultation
6. Provide resources to develop skills and knowledge.
April 2011, Budapest High level PCP event: Preco Health and Aging well
workshop conclusions
1. Connected Health -> new innovative solutions integrated into existing services,
securing also deployment. cross-sector cooperation, integrated care
2. Common/joint Needs assessment
3. Functional user requirements
4. Demonstrate benefit -> cost /impact analysis needed
5. Common patient data platform, sharing (open) data: Making use of Epsos
standards, addressing possibly several needs & creating several solutions in the same
project
6. Make use of patient / citizens /clinician involvement (i.e. co-creation methods,
including Living Labs) throughout the whole PCP process, PCP 0 phase important!
7. Thematic PCP Best practice data bank + Guidance book needed, illustrating
concrete issues and how to tackle these.
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1. Political / policy level clear and pronounced support for PCP and eHealth uptake needed.
Recommendation: Create a clear and strong PCP awareness raising campaign.
Following is a non- exclusive list of issues and recommendations based on the overall evidence
and understanding acquired during the Preco –project, including best practice case analysis,
interaction with supply and demand side actors and other relevant EU-projects:
1. The mandate: Political / policy level clear and pronounced support for PCP and eHealth
uptake needed. Deliver a clear message focusing on the following:
- Demand-driven innovation practices such as PCP do exist and should be used.
- There will be political, financial and other types of support for Demand driven practices
and a clear shift from traditional R&D&I in favor of these new tools.
- These instruments can be used in order to achieve several interconnected targets,
creating win-win-win situations.
- PCP is an instrument allowing investment in the pre -phase instead of paying for
errors/shortcomings in the commercial or post-commercial phase. The challenges for
using PCP as an instrument are not primarily legal but organizational, cultural etc, while
necessary capabilities are not currently inherent in many public organizations.
Preco Key Recommendations:
Following actions will subsequently also have impact on more technical issues and bring about a
change in the PCP field. Concrete PCP actions will create wider understanding and show evidence of
when and how more precisely to conduct PCP.
Deliver a clear message that the Demand driven innovation tool PCP exists and is
given new priority as instrument for acquiring R&D&I
Clear the regulatory status of PCP, i.e. not managed under the European
procurement directives, basically question of transparent and non-discriminatory
contract- and IPR management
Raise awareness of the possibilities of PCP as a tool among demand and supply side
actors.
Emphasize PCPs systematic nature connecting the complete innovation chain; i.e.
real needs assessment, R&D and deployment/commercialization.
Crate supportive tools for knowledge/skills transfer, charing of best practices etc
Keep PCP approaches flexible and as open as possible.
Secure more support & funding for networking and deal-making across EU and
Contracting Authorities
Offer more funding for joint PCP work aiming at focused collaboration.
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2. The skills: Invest in awareness raising, education and training
PCP / eHealth awareness, knowledge, capabilities and real life experience exist at the moment
only among Contacting authorities in Member States /Regions where centralized support has been
in place for PCP /eHealth (such as the UK and Holland). However, successful PCP actions have
taken place or will be soon taking place also in other Member States because of the role and work
taken by facilitating organization such as Innovation agencies and consultancies. Most European
contracting authorities are not at this moment capable of embarking on PCP activities on their
own
There is a strong need to invest in eHealth/ PCP awareness raising, training and education for
professionals, but also to focus on reducing the asymmetry in capabilities, information and
knowledge between health and ICT professionals (in the public services) and motivated patients,
and thereby strengthen stakeholder engagement. All of this should contribute to a continuous
improvement of professional expertise as medical knowledge advances, to more effective patient
information, empowerment, choice, and growth in responsibility and self-management through
eHealth solutions.
It is also necessary to understand that the healthcare sector is still fairly conservative and has not
modernized its culture and working methods to such extend as some others sectors have. At this
moment innovations and pro-active development activities (including process innovations) are
often a no-man’s land in the healthcare organizations.
Silo leadership and management, where ICT, procurement and medical experts all have their own
responsibilities and objectives does not create incentives to fully exploit the possibilities in the so
called grey areas where ownership of issues is divided.
The learning curve theory: Learning by doing is a crucial factor for demand and supply side actors
alike. Companies need to become familiar also with PCP as a tool, with the methodology/issues
and the opportunities it allows for. Companies with understanding and experience are likely to
deliver more efficient results.
The adoption and implementation of EU commercial procurement directives can serve as a useful
practical example of awareness raising and training. At least in the Finnish context an intensive
and broad array of courses directed to public authorities and supply side actors were and are still
taking place and have created a knowledge base. However, public authorities are still in the early
phase of a learning curve as to even adopting innovative requirements in their normal commercial
procurement practices.
PCP is a new, often completely unknown and fairly complex tool. It is therefore evident that a
strong awareness raising and training campaign is needed if PCP is to become firstly known as a
practice, and secondly taken into use as a regular practice where and when appropriate.
Recommendations:
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- Provide public authorities with practical external expertise on the different aspects of the
PCP process and eHealth to start with. Aim at capabilities creation within the organization
itself at longer term. I.e. as the knowledge base grows through practical experience, these
capabilities can be then later found within the contracting authority itself.
- Create innovation friendly working environments with incentives to take and show
leadership. Allow lead-users within the healthcare organization to catalyze fresh
innovations using their genuine understanding of the problems.
- In the longer term consider creating new “professions” or expertise, combining e.g. ICT and
medical competences.
- Launch a systematic PCP awareness raising and training programme, directed towards both
the demand and supply side actors, EU-wide and nationally/regionally.
3. Learning together, trans-European exchange of experience
In spite of the structural differences across regional and National Health Service systems, diffusion
of eHealth solutions should be accelerated through further improved cooperation between the EU
and Member States, among Member States and between their national competent centers.
Recommendations:
- Create wider and more in depth awareness among policy makers and other stakeholders
within the Health sector concerning the possibilities of PCP eHealth. Key topics to be
promoted should be related to health reform and policy priorities, including urgently
needed efficiency gains of workflow processes and related resource savings.
- Establish a web based PCP platform, with thematic section, which includes guidance on
how to undertake PCP/eHealth, best practice examples (programmes, financial
instruments, best practice cases ect).
- In the longer run possibly EU-level and/or national focal points with PCP/ Innovation
procurement and thematic expertise
- Use joint pre-commercial procurement actions and policy initiatives to create collaborative
learning and bring together forerunners countries/regions and newcomers. Use
Knowledge transfer and evaluation (even in real life testing environments) to understand
where and how organizational eHealth models used are scalable and exportable to other
regions.
4. Integrated policies and care - Cross sector cooperation - different levels of innovation
It will be mandatory to better mainstream and align eHealth implementations with strategic
health policy goals. eHealth should not be the objective of a standalone strategy, but be fully
integrated into overall health policies.
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In the context of health system development, Member States should improve ICT facilitated co-
operation beyond core healthcare service providers towards an integrated well-being and care
approach which includes social care providers, ambient assisted living (AAL) initiatives, and
prevention and wellbeing services – i.e. secure continuity of care.
The Danish Preco best practice cases study shows that user-driven PCP can offer a valuable
systematic tool in acquiring above described integrated care solutions in an effective manner. The
Danish cases are mainly in the Low-technology / complex product-service systems category.
The main focus of EU PCP objectives has been on innovative High-Technology products, often
serving as “standalone” solutions when introduced in the public services. However, it is also
possible to acquire High-Technology/ complex product-service systems through PCP. This
possibility should be considered as an interesting way of remodeling the services in a holistic way,
providing also cost/efficiency gains in the care delivery systems.
Recommendations:
- Mainstream PCP into public healthcare service- , procurement- and innovation strategies.
- PCP approaches and rationale should also take into consideration that PCP can be used
to acquire different types and different levels of innovation. Do not only focus on
standalone High-tech innovations but also on those having a positive impact on the
complete care path, bringing cost-efficiency gains and better quality services.
5. eHealth governance – common EU-wide and national thematic priorities:
The EC-facilitated eHealth Governance Initiative of Member States is a good opportunity to
associate eHealth policy with the mainstream of health policy objectives. Relevant health system
priorities include the safety and quality of healthcare/social care; provision of appropriate
information to patients; patient empowerment; patient choice; and cross-border relations that
support continuity of care. The Governance Initiative also provides a powerful opportunity for all
Member States to collaboratively design the future European eHealth strategy and infrastructure.
Countries are experiencing similar challenges and the same pressure on health system and societal
resources; they can cooperatively build on exemplary, successful eHealth practice.
PCP offers a tool to address jointly these common challenges and needs in a structured and
holistic way. In the framework for Horizon 2020 it is advisable to jointly agree upon some
thematic priority areas/topics to be addressed through Demand driven policies and actions.
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Recommendations:
- One clear PCP focus area should be the already established Lead market eHealth.
Focus on some jointly prioritized areas within this sector i.e. develop and implement
common needs assessments involving innovative and pro-active demand side actors
to start with.
- Establish networks of Contacting authorities interested in this type of joint Needs
assessment and market sounding exercises. This type of activity is also likely to have
as impact quality and outcome wise better PCP project proposal. Public R&D&I
money should be delivered to projects where the actors have real interest and also
capabilities to bring forwards successful PCP activities.
6. Financing common challenges - ensuring deployment and real business
There is no agreement on how relevant financial challenges indeed are. Perhaps financing issues
are less important than sometimes considered; on the other hand, a number of newcomer
countries to eHealth and PCP do see the dominant challenge as a financial one.
In any case it is fairly evident that at this early stage of PCP implementation financial incentives are
very important in order to make PCP a more commonly and more specifically jointly (even cross-
border) used tool to acquire innovations.
Some additional support (money, testing environments etc) to companies/ innovations which have
managed to reach the prototype and testing phases of a PCP eHealth process could make the
difference. This is especially important for SMEs, who at this stage of the PCP process have
already proven that their solutions are in need and that they are likely to fit the existing service
structures. A “final support action” could secure deployment and even wider diffusion of the
innovation.
More private finance and venture capital is also needed to support in particular the PCP prototype
and testing/deployment/commercialization phase of the innovation life cycle (see analog above).
This will help to convince even SMEs to participate in PCP processes, while sound reimbursement
and business models throughout the innovation chain are more evident.
Recommendations:
- Make a balance shift in the Innovation Policy. Direct money from traditional R&D&I
financing towards financing of joint demand-driven activities especially in emerging lead
market fields such as PCP eHealth. This will allow tackling the complete Innovation chain,
including the deployment.
- Consider even tax measures such as tax exemptions to companies involved in PCP actions
– in particular to growth oriented SMEs. More than half of the EU Member States already
have tax instruments in use, which support R&D&I activities.
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- More R&D&I money, as catalyzer, should be directed to focused networking and
collaboration and joint working on PCP eHealth - both on EU and national levels
- Offer additional support (money, testing environments etc) to companies/ innovations
which have managed to reach the prototype and testing phases of a PCP eHealth process.
- Crete a link between PCP and venture capital activities. Venture capital firms need
promising clients and do wish to invest in innovations for which there is an established
need and most likely also a market.
7. More systematic and better industrial and stakeholder involvement & user-driven
innovation
Representatives of the eHealth industry and other stakeholder groups would be keen to see an
approach which assures co-shaping in developing and implementing eHealth. Health system actors
should explore together how to deliver innovative eHealth solutions to respond better to the
changing and diverse needs of Europe’s citizens and patients. Possibilities to this depend on
people’s individual health and social situations, capabilities, and motivation to become actively
involved in their own treatment. The EU Horizon 2020 Strategy provides an appropriate base for
such activities.
Recommendations:
- Use a case adopted PCP process providing a systematic tool for co-creation. Focus in
particular on a thorough early joint problem area definition/ needs assessment guiding the
R&D&I process to right direction to start with. Aim to address real needs both from the
service providers and users (clinicians, patients) point of view.
- Involve the end-users throughout the PCP process when appropriate using case adopted
tools and models for this purpose (see the user-driven PCP tool kit description).
- Provide better access to real life testing environments, such as hospitals, primary care
institutions and homes, especially in the prototype and deployment/commercialization
phase of PCP – possibly also as a cross-border exercise.
8. Competition and risk management – market stimulation - SMEs involvement in PCP
One neglected factor of sound risk management is to reflect over the alternative ways of acquiring
needed solutions. There is clear evidence that too often normal commercial procurement renders
solutions that do not meet the expected outcomes and show to be much more expensive in the
longer run than originally calculated. Post-commercial procurement adjustments and
improvements create additional costs and “headaches”. What was maybe originally considered as
the cheapest bid can become the most expensive and yet not fulfill the needs. PCP allows tackling
these issues in a systematic and holistic pre-commercial environment.
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The EU PCP model (COM 799) envisages competition among suppliers. Competition is very
important in order to acquire the best and most innovative & cost/efficient solution.
However, it is also important to allow creation and use of flexible PCP models, which can adapt to
case based conditions. The more complex or technologically challenging the problem (and PCP
process) is, more difficult it can be for the SMEs to participate. A flexible approach can make the
SMEs involvement easier and allow for better risk/benefit management for all parties involved.
SMEs can profit from entering a PCP process where they can learn from international companies
and get familiar with the contracting authority needs and environment.
Transparent and non-discriminatory contract management and IPR protection throughout a
flexible PCP process can secure both a learning process and a business cases even for the SMEs
active in the Health/Assisted Living sector. A non-competitive, transparent and thorough needs
assessment and PCP contract specification phase can make it easier for the SMEs to participate in
a PCP competition (while thorough ground work already done jointly).
Recommendations:
- Allow for flexible case adopted PCP approaches. The PCP models should secure
competition and also more open innovation type of practices and combinations of these.
- Make it possible for SMEs, when feasible, also to participate in the PCP process as a
consortium or through teaming up with bigger companies in an open innovation
framework.
- Develop a sound Business case to start with, make “early investment rationale” visible.
- Financial support also for the later phases of PCP will facilitate SMEs involvement (see
chapter: Financing challenges).
9. Evaluation and impact assessment – cost/benefit analysis to show evidence
The issues involved in the evaluation, monitoring/benchmarking and socio-economic impact
assessment of eHealth investments and services are increasingly important topic. In the times
where cost efficiency of the public services are in focus thorough high quality cost/benefit analysis
of PCP/eHealth investment can help to justify the investment and to evaluate whether PCP in the
specific topic should take place to start with. In prospective forecasts, eHealth usually shows
significant savings, but often empirical studies do not (yet) validate these.
Recommendations:
- Explore the role of national competence centres in evaluating and monitoring eHealth
provisions, implementation and deployment, especially in situations where public demand
side structures are fragmented and skills are still scarce.
- Economic and financial costs and benefits must be dealt with as integrated part of all
healthcare investment, including those acquired through PCP. Public authorities should be
asked to undertake such evaluation and they should also be trained to do so.
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10. Standardization & Re-use of individual patient health data.
The strong felt requirement for further standardization and, in particular, specification and
certification efforts is evident. Such common initiatives should focus on well-defined and bounded
applications and data models, like in epSOS, and they need to closely engage health professionals
and nurses to assure that their needs are met. Member States should be encouraged to enact
legislation that will help to produce such standards and require their testing, certification and
application.
Incorporating eHealth-related standards in eHealth procurement procedures and tender
specifications is another request made. Here EC guidelines may prove helpful.
A largely neglected domain in national eHealth roadmaps is the re-use of patient data in
anonymised form. To reap further benefits from eHealth solutions for public health, clinical
research, and patient safety, this topic needs heightened attention and support initiatives from
both EU and the Member States.
Recommendations: Use PCP actions (regional, national or EU-cross-border) to help provide a
working platform to align and agree upon joint standards and appropriate re-use of patient data.
These types of activities can in turn influence positively even business wise sound and successful
PCP actions.
11. Interoperability:
In the longer term, the EU aims to agree on processes for the implementation of interoperable
solutions throughout Europe. The initiative will enable easy and fast access to a citizen’s electronic
health record or a targeted extract from it (such as a patient summary or emergency data), from
anywhere in Europe, at any time. Recommendations from Smart Personal Health EU project:
Promoting (interoperable) personal health systems for a healthier Europe:
(sph.continuaalliance.org/docs/SmartPersonalHealth_publications).
Recommendations: Use PCP as a driver for better interoperability and vice versa, interoperability
can further enhance and facilitate the use of PCP as a tool for R&D&I in the eHealth field. This
could be important especially considering cross-border PCP actions.
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Appendix 1: PRECO eHealth case descriptions
Case 1: eAmbulance: Electronic registration of patients in Jihlava Hospital: Czech Republic
https://www.eambulance.cz/
This case study describes the development of a new eHealth service for citizens of Vysocina, achieved in cooperation of Vysočina Region (CZ) with the Institute for Information Industry (Taiwan). The case is dealing with the successful preparation, implementation and pilot operation of the Electronic Registration of Patients in Jihlava Hospital during the year 2010. The project has got finally the name eAmbulance.
Background
Vysocina is ensuring health services in several regional hospitals, including hospital in the main regional city Jihlava. The idea to suggest to citizens better, cost effective and innovative system for electronic registration of patients was in the air. The preliminary intention was to discover the online system, which would be user-friendly and interactive, saving time both for citizens and for administrative personal of hospitals.
It was discovered, that the traditional process of Public Procurement may not bring the most innovative solution, so some elements of PCP were applied.
The most innovative solution, which had already been approved in practice was suggested by the largest ICT organization in Taiwan - Institute for Information Industry.
Based on the information from technological experts from Vysocina IT Department, and on the demand expressed by JIhlava hospital, the President of Vysocina, Mr. Jiri Behounek, sent a letter to the pre-selected partner in Taiwan in December 2009 expressing the interest to cooperate on a pilot project: e-Registration Systems in the network of regional hospitals. The e-Registration System would enable advanced and friendly internet registration and voice registration functions to the citizens improving the current registration service provided by the hospital.
The Taiwanese delegation has visited Vysocina Region and after negotiations has submitted an official agreement for formal approval by the Region.. The implementation of the system began in April 2010, testing was lasting till Autumn 2010, and from Spring 2011 the system is fully operational.
Project Objectives and Benefits
To improve the efficiency and quality of the registration service provided by the Hospital to the Region’s citizens through the innovative e-Registration System with functions of advanced and friendly Internet registration and voice registration in the Regional Jihlava Hospital.
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To pilot the new service (e-Registration) for the future implementation in the whole network of Regional Hospitals and to improve in general future healthcare system in Vysocina.
To utilize non-European know-how from Taiwan in order to rise the level of healthcare services for Vysocina citizens and to reach recognition as the leading “e-Healthy Region” in the Czech Republic.
To provide all users of the system, including doctors, management of the Hospital and regional administration staff involved, with the easy-to-use system to evaluate the eHealth service provision in Vysocina.
All those objectives were achieved, and during the preparations of the pilot some innovations of the system were developed by the Czech ICT team in cooperation with the Taiwanese (see below).
Why is this project to be considered as pre-commercial procurement?
The case is an example of practical attempt to support innovation in Public Purchasing of technological solutions. The selection of the innovative solution and the whole process of the project cooperation include the majority of the phases of the Pre-commercial procurement of innovation, based on the typical research and innovation life-cycle, transforming an idea into a product/service. There are in particularly:
Direct public R&D investment in the first phases of the project o Phase 1: Exploration of the solution of the problem of missing electronic system of
registration in regional hospitals – the feasibility study has been developed, contacting some of the regional suppliers
o Phase 2: R&D up to prototype – direct investment into the gap analysis, fiction tailoring and the ICT environment preparation – customization of the existing service
o Phase 3: The pilot product testing – in one of the regional hospital (Jihlava)
Sharing of the costs – the procurer (Vysocina) and the selected supplier (III Taiwan) agreed to share the costs of the Phases 2 and 3
Sharing of the R&D risks – in case the system would fail for any reason
Commercialisation of the final product – the electronic registration system is going to be implemented as a service in all of the regional hospitals, based upon the regular public procurement
Project Tasks
Kick off
Gap analysis and function tailoring
ICT environment preparation and system installation
Training for basic data preparation
Basic data entry and verification
Training for ICT staff
Training for end users
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System integration and parallel testing
On production preparation
On production and stand by
Maintenance service
Pilot Cost Estimation
For the pilot project implementation the shared costs model was agreed by both sides. The overall budget of the pilots was slightly over 120.000 EUR, from which 2/3 was financed by Vysocina and 1/3 was co-
financed from Taiwan national funds. The break cost estimation for the e-Registraion System implementation and one year maintenance support for Jihlava Hospital is listed in table 1.
Table 1. Project Cost Estimation in CZK
Project multidisciplinary team
For the pilot project “e-Registration System in Jihlava Hospital” a multidisciplinary team was created of experts from Vysocina Regional Authority + JIhlava Hospital + Taiwan team:
From the Czech side, the Project Manager was dedicated from the administrative staff of Vysocina Regional Authority (which is supervising and financing regional hospitals). The ICT team included experts from Regional IT department as well as from Jihlava Hospital IT department.
The Taiwan partner has created a project team consisting of members with extensive e-Hospital and e-Healthcare experience from III, e-ToYou International Inc. (subsidiary company of III) and Soloman Solution Services Corporation (cooperative partner of III). Those three companies have successfully planned and implemented a number of projects in e-Hospital and e-Healthcare systems. The team was managed by the Account manager. The project organisation is displayed in figure 3.
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Selected Taiwan supplier - Company Profile
Institute for Information Industry (III), http://www.iii.org.tw, was established in 1979, through the joint efforts of public and private sectors, as a Non-Government Organization (NGO) supported by the Ministry of Economic Affairs. Currently, with 1,900 system/software engineers, III is the largest ICT organization in Taiwan. In the fields of Hospital Information Systems (HIS), National Health Insurance Systems (NHIS), and Health Information Networks (HIN), III has more than 20 years of experience successfully planning and implementing these systems. III is a major health-related systems provider in Taiwan with international implementation experiences as well. Keeping up with the latest developments in the fast growing field of ICT technology, III consistently provides the best quality solutions of software, hardware, and services.
Figure 3. The multidisciplinary project team in the eAmbulance project.
Innovation developed during the pilot
The original system of eRegistration, successfully running in Taiwan, was significantly innovated during the preparation for the implementation in the Czech Republic. First of all, some changes were done in the design of the main interface with users, taking into account differences between graphic culture of Europeans and Taiwanese. Then, the very process of registration of patients was simplified towards higher user-friendliness, due to high level of programmers in the Czech team, some functionalities were reduced for 1 click instead of 3 (“less clicking”) during the registration. The third, the system was enriched with the automated report generating utility – on demand of
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doctors and management of the Hospital as well as of the Region. For doctors, the summary of patient’s records was introduced, as well as so called “Black list” of those non-disciplined users, which are often registering themselves for a visit to a doctor, but never come. After 3 time of reservation without visit following, such users are erased from the system with restrictions for the future registration in order to release the time slots for those with real needs.
As the next significant innovation upon the original system, the Czech team has developed the notification service for patients: the first notification is coming directly after the registration to a doctor, the second is confirming the time slot and the reservation, the last is coming the day before the visit planned as a “remind” message. The messages are sent to email or as SMS to a mobile- depending on the choice of the user.
The next diagram shows ICT environment preparation and system installation (fig. 4).
Figure 4. From operational point of view, the system is very user friendly and is operable from any Internet browser.
Conclusions
The case eAmbulance, https://www.eambulance.cz/, is an example of practical attempt to support innovation in Public Purchasing of technological solution for improving eHealth services in Vysocina Region.
• Intention: to investigate and pilot the innovative technological solution for online registration (including voice registration) of patients for hospitals in Vysocina
• Partners: IT department of Vysocina RA + Institute for Information Industry (TchaiWan)
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• Objective: to provide better eHealth services to citizens in Vysocina (customers of hospitals)
• Timing: All phases during 2010, piloted in Jihlava hospital from Spring 2011 – now fully operational service
The selection of the approved and innovative solution and the whole process of the project cooperation include the majority of the phases of the so called Pre-commercial procurement of innovation, based on the typical research and innovation life-cycle, transforming an idea into a product/service. Direct benefits are:
• relatively low costs of the initial analyses of the SoA situation (missing electronic system of registration of patients in regional/national hospitals)
• effective system of pilot testing and evaluation, all phases during 2010, piloted in Jihlava hospital from Spring 2011 – now fully operational service
• risk and costs sharing principles with the selected supplier, the budget over 120.000 EUR (2/3 financed by Vysocina and 1/3 co-financed from Taiwan national funds)
After the successful piloting in Jihlava Hospital, the eAmbulance project is now prepared for the implementation in the next 5 regional hospitals in Vysocina . Due to the fact, that the overall costs for the implementation of eRegistration system are under the limit stated for the traditional Public Procurement, no other procurement procedures are required.
Case 2: The hospital bed of the future: Denmark
The second case is collected from Denmark and concerns a procurement project called ‘The hospital bed of the future’. The hospital bed of the future project is a pre-commercial project intended to lead to an innovative bed evolving in the Region Midtjylland. The basic problem that made out the starting point for the project was the observation that nurses spend too little time with patients. It was found that the delivery of care in interaction with patients takes only 1/3 of nurses’ working time. The project followed from the ambition to increase the share of the time nurses spent together with patients to 60%. The project is still running and was initially scheduled to be finished 2012. The final outcome of the project is therefore not certain at this stage. Components that have been considered to be integrated into the final bed solution are scales, humidity sensors, and screens for television and computer/ Internet access.
The project should create the basis of commercial procurement of hospital beds to supply the whole Randers Regional Hospital (who procures 100 beds a year, which is equal to an investment of 3.000.000 DKK a year). Ideally, the project could also provide a basis for procurement of hospitals beds to the whole region including both hospitals, nursing homes etc. (which lies in the area of 600 beds a year – at the cost of roughly 18.000.000 DKK a year). The Price of a hospital bed is 30.000 DKK. The hospital bed of the future project is a part of a larger project named ‘More time to the patient’. The other two projects have to do with self-cleaning toilets and room-dividers. The project(s) are anchored at Randers Regional Hospital, Denmark.
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Randers hospital is currently undergoing a transition from being a regular hospital to an emergency hospital. Emergency hospitals are set-up to treat any kind of care-seeking patients. Regular hospitals are generally smaller and accept only planned or pre-arranged admitting of patients where diseases/ problems as well as treatments are already established. For the hospital the transition required different kinds of upgrading. They needed to be able to provide any kind of medical specialty; hire new doctors; procure new kinds of equipments. They also needed to establish a network of University Hospitals in order to be able to transfer patients requiring specialist treatments.
Background
This project developed at Region Midtjylland which is the regional authority responsible for healthcare, including hospitals, and practitioners of that part of Denmark. The initiative and idea for the project came from a Head Nurse at Randers Hospital, who saw this as a way to respond to the many complaints from patients about lack of interaction with the health care staff.
What further justified the project was an internal study, which showed that the health care staff only spent 30% of their time with the patients. The Head Nurse continued arguing for the need for the project, which she named ‘More time for the patient’ – and after about 5 years – she was granted 5.000.000 DKK for the project from the Regional board (the political leadership of the region).
Midtlab, an internal innovation-hub in the Region Midtjylland, got involved to facilitate the project. Their main objective is to contribute to innovation in the public sector and motivate social entrepreneurship. Their special competences are to create and support cross-sectional partnerships (both public-public partnerships, and public-private partnerships). Parallel with this, an internal project manager at Randers Regional Hospital was selected. This manager’s job was to coordinate the project internally but also to take part in outlining the project specifications. This manager is also handling the transition at Randers Regional Hospitals – from regular hospital to emergency hospital, which means that part of his job is also to synchronize the new initiatives/efforts. With the internal (regional) group in place the procurement process started.
Although this project is managed within the Region Midtjylland, what is noteworthy is that those facilitating the project are not the same organisations that will eventually buy the innovative bed. The potential procurer would be hospitals in the region and from elsewhere, but, also individuals where considered as future customers. In that sense the actual project is an example of catalytic procurement, i.e. public procurement of innovation where the procurer creates demand on behalf of others. The ambition was to develop a bed that is flexible enough to be useful for hospitals as well as for private homes: It should be a bed useful for future care wherever it will take place.
The Region Midtjylland would be one obvious procurer for some of the beds. Also a Region in Sweden that is part of the project belongs among future procurers.
The project, partners and selection mechanisms
The tender process for the development project took place in 2009. The 23 June that year an information meeting was held at Randers hospital. The meeting welcomed suppliers of beds and other assisting technologies in health tech, design firms, research institutions, architects specialities in hospital design, and other companies with interest in development or marketing of
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health tech1. Competitive dialogue was used as the procurement procedure. The selected providers were: Design Partners (design firm); Cetrea (an IT developer), Linak (developer of actuator systems and IT); Danish technological institute (a non-profit knowledge dissemination agency; KR beds (a bed manufacturer).
The providers for the project were initially to be selected based on financially robustness. In practice, however this did not play such a big role. There were three points that had an impact on selection. Participants should demonstrate:
Willingness to leave present solutions (or present paradigm) and think out of the box
Willingness to collaborate with the other partners and assign responsibility to these
Willingness to change technology and manufacturing procedure (for instance from steel to aluminium or carbon fibre).
The project was initially organised in cycles. In the agreement the partners committed to hand in a prototype for real-life testing every three months. The partners would receive a payment for each prototype delivered. The amount of money for the individual prototype was to be negotiated on the way. This envisaged pace of a prototype delivered every three months showed, at least the first years, to be too ambitious.
The budget for the project was DKK 2.000.000 which might be seen as a relative small amount. The procurers saw the small budget as an advantage, because it separated the pre-commercial development project from regular procurement contract-wise. The idea is that the same partners will be involved also in subsequent commercial phases. The budget for the pre-commercial procurement project will be spent on the creation of prototypes. Besides the project funding Randers Regional Hospital will also provide possibilities for prototype-testing with patients.
Interaction and learning
The set-up meant that the suppliers had to engage in different kinds of interacting and learning activities. This concerned all aspects of the new hospital bed, including software, design and construction. This included also interacting with firms and adoption of technologies from areas outside the hospital bed industry. Examples are suppliers of handicap equipment, as well as one large hotel chain, Scandic Hotel. This company could contribute with experiences from earlier procurements of beds for handicapped guests. Scandic’s involvement was also in the role of future customer/ user. This company would also be interested in procuring the beds developed in the project. Another source of learning was the airplane manufacturer industry as manifested in the project’s close contact with British Airways. The project drew on experiences made in design of chairs and beds for first class. Some technology has also been adopted from the weapons industry.
1 Regionshospitalet Randers Invitation til Informationsmøde forud for udbud af Offentlig-Privat-Innovationsprojekt:
Udvikling af fremtidens hospitalssæng i den moderne sengestue. Invitation letter of 5 June, 2009.
http://www.regionshospitalet-randers.dk/files/Hospital/Randers/Aktuelt%20og%20presse/Nyheder-
Pressemeddelelser/2009/2009%20Invitation%20til%20informationsm%C3%B8de_OPI%20projekt.PDF Accessed
2011-10-04.
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Interaction with users was also a component in the project. All prototypes will be tested with users (patients) in real-life situations. User interaction was not only used as a way of testing developed prototypes, but also as a means to get insights at the beginning of the project. One of the first actions made in the project was to set up a test patient bed at the public library in Randers. One old and one current bed were set up. This enabled members of public to test the bed and give comments. The employees at the partner companies were also invited to visit and ‘work’ at the hospital for a few days. This created good conditions for collaboration in the project and good understanding of the different difficulties, which can be found in the use-situation of the hospital bed.
Other experts of user-driven innovation were involved. During the project there has been made contact with anthropologists, as well as technology and process researchers from Danish Technological Institute. Both health care staff and patients have been interviewed. Some examples of issues identified in these interactions with patients are as follows: How would a bed facilitate mobility for the patient?
How would it be possible for a bed to activate patients? These issues where discussed a lot among patients and professionals. This was useful because for many professionals and people within care treatment as this opened up new ways of understanding what a bed might mean from a patient’s perspective.
Experiences
As was stated above, the project is still underway. Therefore is it hard at this stage to give any general conclusions regarding to what extent the project was successful. Some experiences that have been concerning the development of the project is summarised in the following.
The project was delayed nine months due to legal problems essentially stemming from lack of knowledge and experience among the lawyers assigned to the project. One general reflection reported is that “procurement agreements are time-consuming to develop”. In this case it took time to find out what kind of procurement procedure to use and how to use it – as well as what kind of contract agreement to set up. The procurement procedure chosen to select partners for the pre-commercial stages of the project was the Competitive dialogue. The reason for choosing the Competitive dialogue was that it was not initially established in detail what kind of product that would eventually to be procured. Neither existed knowledge on how the final solution should work. This could only be established by entering into dialogue. The reason for choosing the Competitive dialogue was thus a perceived lack of information. This reflects a view of the Competitive dialogue as a procedure to use in order to build up knowledge in order to, at a later stage, being able to engage in dialogue with potential manufacturers.
Although the Competitive dialogue has been used in Denmark before mainly in the construction industry (for contracts on infrastructure like bridges and hospitals), the lawyers who worked with this project lacked specific experience on how to carry out public procurement according to that procedure. The lawyers had to be taught about this procedure before they could give legal advice. Delays where also caused by uncertainties in relation to intellectual property. In spite of the contractual problems the collaborations appears to work well. The fact that work is continuing although contracts are still not finished suggest that there prevails trust among the partners in the project.
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One reason why the process took place the way it did was because of a strong ‘champion’ involved in the project, the Head Nurse. She was passionate about the project and the problem it would solve. She also had the ability to talk to everybody in the organizations – on all hierarchy levels.
There was also strong political support for the project. Politically there had been a lot of attention to another large project, the development of a new regional ‘University Hospital’ in Skejby, a suburb of Århus, Denmark. This resulted in a number of complains and dissatisfaction from representatives of the smaller regional hospitals in the area who argued that they were neglected by the Region leaders. This imbalance in the Region created a need for focus on the smaller hospitals, and this project became one way of doing this. The change from regular to emergency hospital that Randers regional hospital was going through was also seen as one of the reasons why this project was initiated.
The project fitted nicely into the currently undergoing upgrade towards becoming an emergency hospital.
For the bed manufacture the beneficial of this process is that they have gained knowledge that has business model implications. One body of knowledge concerns how hospitals operate, which is essential for design and IT people. They need to know details how doctors or nurses work, what is the logic behind what they do and what would they like to do and they are not capable today and/or if currently used equipment prevents them from doing something. The business model for some manufacturers has changed in the way that there has been an increase in the number of people working with design and technology. Firms have come to think of themselves in new ways. One example is about thinking in terms of issues or version. Currently the focus in marketing is on the bed model 2012. This maybe followed by a new model for 2013. Another change concerns their role as experts.
Since the involvement in the project, firms are no more looking at themselves as experts on beds; they have now become aware of that it takes a partnership in order to achieve the future model of beds. These changes have in turn led firms to a focus on more flexible products that in turn may improve market positions. There are also positive network effects for participating firms in the sense that contacts established within this project are also utilised in other projects. For instance, participating firms have found collaborators from for instance the technical institute, which they use in other as well.
On observation report concerns the tension between efficiency-based regular public procurement and public procurement of innovation. As conventional procurement departments are not initiating any pre-commercial projects, they have no experience from these kinds of projects. Therefore they could offer no help in relation to projects like this. They are driven by old paradigms like for instance: larger number = more discount, and they have a hard time thing outside these principles. This means that solutions, becomes expensive in the long run – because they lack flexibility (for instance – there are not the same demands to all hospital beds, and therefore buying the same kind for all situations means more expenses)
A final effect concerns public relations and image. For all the partners it is seen as prestigious to be part of the project and to have close contact with the other participants.
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Case 3: The patient briefcase: Denmark
The patient briefcase is a communication device that enables communication between the patient and medical staff at the hospital developed for patients suffering from Chronic Obstructive Pulmonary Disease (COPD), a decease that leads to a limitation of airflow to and from the lungs often caused by tobacco smoking. This portable telemedicine system consists of two components; the patient brief case and a workstation for medical staff.
Background
The project came out of a discussion between medical staff on different solutions to offer care outside the hospital. A group of physicians and nurses brought forward ideas about developing some kind of ambulating health service unit that would be able to provide health care services in the homes of the patients. The idea was based on research findings demonstrating the superiority of health care delivered in patients’ homes rather than in hospitals. Dr Michael Hansen Nord, at the time Chief physician at the Medicine clinic of Svendborg Hospital in Denmark, who eventually became the champion of the project, had also received some request from people he know from earlier European projects about possible telemedicine solutions. The principal decision eventually made was to develop a solution that basically consisted of a communication line between patient and hospital.
This decision eventually led to the development of the patient briefcase. The system consists of the patient briefcase that is used by the patient, and a workstation used by medical staff at the hospital.
The patient briefcase enables virtual consultation where the physician located at the hospital communicates with the patient in his/ her home (or wherever he/ she is located). The hospital-side of the system consists of a work station and three screens. At the agreed time the hospital calls the patient. A part from transmission of sound and video, the system also transfers measurement data from the patient, such as heart rate and/or blood pressure. The system offered several improvements as follows:
Patients could be sent home from hospital within 48 hours instead of 6 -7 days. Therefore;
Release of hospital beds and;
Reduced workload/ reduction of workforce
Improved health service quality as the system enable treatment in the home of the patient; as this creates
Increased quality of life for patients and;
Increased effects of the health care provided.
The evolution of the project is summarised in table 1. The initial ideas where formulated in 2006. Dr Hansen Nord contacted the owner of the ICT firm. He gave a list of requirements to the firm.
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2006 Initial ideas
2006/2007 First patient
2007 Attention in media and among different support agencies
2008 Regional contract
2009 975 patients
2010 National contract
(?) International contracts
Table 2. Time line of the evolution of the patient briefcase.
If one looks how the project evolved it is possible to distinguish between different phases.
These phases correspond largely with phases 1-4 included in the PCP model2, solution exploration, prototyping, original development of limited volume and commercialisation. In the first phases, interaction with different categories of users was a central element in the development (table 2; figure 5).
The initial specification given to the supplier was basically functional, in the sense that it described what the system should be able to do, rather than in technical detail how the system should do it. The initial question given to the developer was formulated as a question: Would you be able to do this? Requirements given were as follows: The solution should be simple, and old patients should be able to use it, it should not look like a computer, it should be water (and coffee) safe, mobile, robust and hygienic. An employee at the IT firm worked on a solution and came back some 8-10 days later with a suggestion.
In the next phase, a group of nurses were assigned to the project. These nurses collaborated closely with the supplier. All kinds of information were needed to achieve a good design. Issues discussed where for instance: What does the user located at the hospital need to see on her screens? What information is needed? What things can the patient manage? There was also an array of technical issues that needed to be settled. The developers needed to achieve an acceptable quality of picture and sound. Another issue concerned communication technology. The first version supported fixed-net communication and satellite communication.
The requirement of simplicity led to a solution with only two control buttons; one to turn the patient briefcase on and off, and one for making emergency calls to the hospital.
2 See Section 2 or European Commission, 2007. Pre-commercial procurement: Driving innovation to
ensure sustainable high quality public services in Europe. Brussels, 14.12.2007 COM
2007:799 final
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Then followed trials where patients were involved. Initially five patient briefcases were produced. Initial tests were conducted in a small laboratory at the hospital with a small group of patients who were asked to test the usability of the patient briefcase. Next, a selected group of patients tried to use the patient briefcase from their homes. For several weeks, several times a week, patients participated in trial consultations enabled through the patient briefcase. Both user experiences from patients and nurses were collected.
The outcome of these test activities was that the next model of the patient briefcase was given an additional control button. A part from an on/ off button and an emergency button, later versions of the patient brief case were also issued with a volume control to enable control and regulation of the sound level. Another thing discovered was the user implications for the medical staff that would interact with the patient. The new requirements were compared with the requirements of a TV host.
The challenge was to be able to maintain good contact with the patient, in the same time as measurement data would appear on the screens. Other issues indentified concerned source of disturbance such as the sound of doors or telephone ringing. Initially also nurses had to re-think their conventional way of interacting with patients. For nurses, ‘conventional’ face-to-face interactions many times include physical contact between nurse and patient. Physical contact was thought of as a way of establishing trust and providing comfort. This perception has changed as the patient briefcase has been used.
Today, the eye-contact enabled by the system is supporting contact. Another reflection made is that patients to large extent prepare for the consultation. The patients appear to perceive the situation as if the medical staff is actually coming to them in their homes. The patient user experience is also different from a visit at the hospital that might sometimes be stressful.
Figure 5. Examples of interaction and learning outcomes in the case of the patient briefcase.
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Throughout the evolution of this project the developers had to deal with some technical challenges. One of the communication solutions that the first version of the patient briefcase relied on was ADSL. The problem was that ADSL was not available everywhere. When patients who lived in areas where ADSL were not available were submitted from hospital with a patient briefcase they would not be able to receive health care through the system. When the healthcare staff contacted TDC, a telecom company, their response time for setting up an ADSL connection would be three weeks. The solution was to make an agreement with TDC to set up an ADSL connection for a patient with a patient briefcase within three hours. This is an agreement that is still in place to today.
Later versions of the patient briefcase rely on 3g and other technologies. The system scans available communication lines and selects the one with best quality.
The road towards commercialisation
The first patients were using the patient briefcase at the end of 2006. In 2007, the patient briefcase rendered a lot of attention in mass media in Denmark. An array of visitors came to study the solutions, and many presentations were given. Different innovation agencies in Denmark supported the further development of the patient briefcase.
The following year, the original project funding had been used. The next step of the project envisaged by the developers would have been to diffuse the patient briefcase to other hospitals in the region. It was here, however the project stalled. In spite of the attention gained in mass media and the fact that the political leadership praised the innovative project, funding required for a commercialisation was not easily accessed. The regional officials could not see how funding from the regional level could happen. The international attention the project had rendered helped the supplier to find a client elsewhere; the first contract awarded to the developer was with a county in Norway.
In this case, the firm that made the pre-commercial development also became the supplier of the commercial solution. Legal experts within the hospital organisation, on national level as well as the EU level were consulted to verify that this would be legally sound. The argument justifying this choice was that the product was so innovative and unique that no-one else would be able to deliver something similar. The intention to sign the contract was published in Statstidende3, an official online publication channel three weeks before the signing. By applying this procedure before the commercial contract was actually signed, any potential competitors were given a chance to come forward. If this had happened, a normal tender call would have been issued.
This did not happen and the contract was awarded without a formal tender procedure. Since March 2010, the patient briefcase is available through framework agreement as at National Procurement Ltd. – Denmark, the central procurement agency in Denmark. The supplier has also contract with a Norwegian hospital, and foresees also interest from England. Other versions of the patient briefcase developed for other types of patients have also been done4.
3 This is (today) a website that publishes legal information and legal implications for citizens, companies, public
authorities and voluntary organizations. www.statstidende.dk (accessed 2011-10-12). 4 Press-release, Medisat. http://www.medisat.dk/en/Start.aspx (accessed 2011-10-12).
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Some experiences for the Patient Briefcase
Some elements that affected the outcomes of the project can be summarised as follows:
The starting point for the project was an innovation friendly workplace. Both medical staff and the head physician who eventually became the project leader at the hospital side were open to innovative ideas given by medical staff or originating from elsewhere and willing to develop them further. Personified by Dr Hansen Nord, but also by other members of staff there was in this sense already from the start a local champion of the intended innovation.
The project involved interactive learning and user involvement that enabled innovation. Although the supplier had not developed products for this market before, they were able to learn how to apply their competence in this context. A central means to achieve this learning was the application of user involvement. Both health care givers and patients were involved, and helped to provide critical input to the final design.
The supplier was willing to take financial risks. The budget for the project was 6 -10 M DKK. DKK 1,2 Million came from public project funding, the rest from the supplier.
There prevailed trust between procurer and supplier. The initial work was carried out without any formal contracts. Obviously this could not have happened unless a high level of trust prevailed between the champion of the project and the supplier.
The project harmonised well with the prevailing health care policy discourse in Denmark, to save hands, and finding ways to deal with the demographical situation where larger numbers of elderly will be taken care of decreasing number of young.
There were no natural resources for advice on legal and other formal aspects of the development project. The first months of the project evolved with a strong focus on the technical aspects of the project. After a while, however there emerged an awareness of issues such as IPR, contracts, patient data integrity etc. The developers searched for advice on these issues in house, within the region or universities. Eventually DKK 1 million was used on lawyer fees to make a contract. It may be argued that as the medical staff provided input and also were heavily involved in the usability aspects of the development of the patient briefcase, a royalty for the hospital would be reasonable. This was also a part of the initial agreement. In the second agreement that was negotiated (after the expiration of the first one) however, the contract between the supplier and the hospital was reduced to a service contract. IPR is with the supplier.
Although the project rendered an innovation not seen before, the most problematic challenges appear not to have been technological, but concerned instead haw to extend the project beyond the local hospital. It was when funding was required, and financial support from the region, that the project lost pace. The region had no organisation that would be able to support the further evolution of the project.
The project involved business model innovation. The exchange mechanism eventually chosen was to leasing the service, not procurement of a product. One reason for leasing rather than procuring was to be able to stay updated with the technological development.
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There prevailed a lack of understanding for dealing with the public sector. Compared to conventional business-to business interaction, the supplier perceived the public partner as slow. Slow decision processes within the public administration. There prevailed also a lack of understanding in relation to public requirements of certain documentation.
A general reflection that emerged in the interviews concern the viability of projects and the possibility to terminate projects that turns out to be less promising. A general recommendation that emerged in the discussions of this case is to consider implementation/ diffusion of the final product already at the development stage. For all projects there should be built in a half time evaluation mechanism and an implementation plan. This evaluation should be set up in a way where one option is to close down projects that are judged as unviable. One could instead then use freed resources in other more promising projects.
An innovation may be an innovation in different ways, and also have different effects. Some characteristics of the patient briefcase can be summarised as follows. The innovation emerged as a response to local demand. It was a product innovation. It was also a process innovation in the sense that the introduction of the patient briefcase made possible a new way of delivering health care services to patients. Another aspect of the process innovation aspect of the patient briefcase was the effect on As similar ideas developed in other countries in parallel with the developments in Denmark, and it is unclear to what extent one can talk about an innovation understood as new to the world. Certainly the patient briefcase was news to the Danish context.
Case 4: HealthLab: Tsaar Peter: Holland
www.health-lab.nl
This case study describes the procurement and implementation of new technologies that enable elderly people to be longer self supporting. For this procurement a Living Lab setting is being used to make sure adaptation of new technologies will be realized.
Background
AMSTA is one of the four largest Health-care institutions of Amsterdam. With the increasing demand for HealthCare due to an ageing society and declining availability of capable staff AMSTA decided it wanted to apply new technology to help them to solve this growing problem. One of the challenges they predicted was the difficulty around the adaption of technology by elderly people.
Normal procurement of technology was not possible due to two causes. First of all they did not exactly now what technology was available and what was needed to implement the available
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technologies, due to the fact that their “customers” were not pro-active in adopting “changes” to their daily life. Secondly they couldn’t see what the use of technology meant for their processes and the requested skills from their employees.
AMSTA’s Leo Versteeg was appointed to find a way to decrease the workload and increase the customer satisfaction by using technology. The new to build location of AMSTA, “Tsaar Peter” was considered to be the right place to do this, because in the architecture of the building it was still possible to make small changes if needed. The building of Tsaar Peter started in 2010 and it was planned to be delivered in august 2011.
In discussions with the VU University in Amsterdam and other knowledge institutions AMSTA decided to make their new building a living lab, where from the start the effect of technology was measured. Since most health care institutions, including AMSTA, have a very limit budget they wanted to make immediately a business cases in savings.
The second challenge, how to make sure their employees have the proper skills, was engaged in collaboration with INHOLLAND, an educational institute. INHOLLAND will join the project and together with their available new courses are being developed ánd applied in their standard curriculum, to make sure the use of technology will be part of their educational process.
Together with the VU University, Waag Society, INHolland and AIM a Living Lab was designed and suppliers of technologies like sensoring, video and app’s were initiated to demonstrate their solutions. A panel of elderly living at Tsaar Peter and a broader panel of elderly was established.
Because of the relatively high costs of organizing a Living Lab that was envisioned other care institutions were involved the join the Living Lab experiment, so costs could be shared. The project was divided into five phases as displayed in table 3.
Project Objectives and Benefits
Increase the quality of care and decrease the request for (not available) staff in the future.
To pilot the use of new technologies before a further roll out within the Amsterdam Metropolitan Area to avoid investments that would not be a success.
To involve senior citizens in the integration and implementation of new technologies and make sure the adaptation of new technologies was secured
To make a business case in a real life environment, realizing that health care institutions have limited budgets
To include the education of current and future employees with regards to the use of innovative technologies and solutions.
Why is this project to be considered as pre-commercial procurement?
The client, AMSTA, had a sense of urge with regards to their health care ambitions due to the problems they were facing with the Care Gap.
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They did not know exactly what solution would be most effective and wanted to avoid a technology push. In teaming up with a knowledge institution and the design of a Living Lab they managed to find an Open Innovation-model to develop custom made solutions.
In comparison, a regular procurement process works in a rather straightforward way. The customer has a need that corresponds with something already available on the market. Most aspects of the procured item are well-known, and the primary variable that determines selection of a certain product is price.
Figure 6. Normal procurement process
Here the situation was different. Within this project there was no clear solution defined. By organizing a living lab (together with a knowledge institution) and involving several suppliers the potential solutions where eventually defined. Based on these results further procurement for other locations will be executed. To do this R&D budget of the VU University combined with an economic subsidy was used.
Figure 7. Health Lab procurement process
Besides this there was an educational institute involved in this project to make sure the knowledge being gathered about the use of technology and the adaption of senior citizens was used to make learning modules. The results of the integration of new, or customized, products are being actively shared with other institutions to help them to choose solutions easier.
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Pilot Cost Estimation
For the execution of this project a broad consortium was gathered. Potential suppliers were asked to demonstrate their solutions for free with the forecast that their solution would be chosen to be used in a broad implementation.
The costs for this experiment are about 450.000 euro’s, but the Living Lab can be used for several experiments. Investment of AMSTA is about 90K, VU University 90K and the rest of the funding is subsidized, also in collaboration with the other Health Care institutions.
First business case: by using sensors in a proper way, the night shift can be twice as efficient. Saving 150-175K on an annual base.
Project multidisciplinary team
Multidisciplinary knowledge and skills are the essence of a procurement process where innovation is the essence. In this project organizing the Living Lab, the involvement of user groups (patients, care taker and relatives of patients), knowledge of care, knowledge of ICT and the ability to make business models required a very multidisciplinary team.
Part of this team was the VU University – department of Social Sciences, a user group of 10 patients, Waag Society for the design of the Living Lab, the local government for exploitation and disseminations, AMSTA as a client and the employees of AMSTA. Also INHolland was involved in this project.
Table 3. Project tasks in the in the case of the HealthLab: Tsaar Peter
Selected Suppliers
The project is still running and not all suppliers are selected. The supplier for sensors is selected and we will use this example in this case study.
Task Results
1 Organize user groups and define needs
Stakeholder groups with definition of needs
2 Design of Living Lab A running Living Lab, including Living Lab methodology and effect measuring instruments
3 Research questions Based on the definition of needs several KPI’s and research questions defined
4 Executing pilots Testing of several solutions in Living Lab with close monitoring of results.
5 Conclusions Lessons learned and best practices. Including business cases.
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Innovating is a SME that is established in 2006 and is specialized in the use or sensors. Within this test-bed that have developed a system where the movement of elderly people was monitored in a very detailed way. The effect of their solution is that during the night the care takers can do “one round” less through the institution while maintaining the same safety. This means a business case between 150 and 175K on an annual base. The investment for a system in all buildings is about 250K.
Innovation developed during the pilot
Sensor technology is a proven technology. The involvement of patients and care takers has led to several adoptions in the product and service around the sensors. During the interaction of this project the following innovations were made to the “proven” sensor technique:
Development of an interface that was friendly for care takers, with not too much information, but enough information to create an own insight
Development of an interface and emergency system for patients that wanted the feeling of security on same level that was when care takers were walking around the perimeter.
Software that analyses the difference from night to night so differences could be noticed and prediction on incidents could be developed (currently under development)
The process of night watch is being analysed and together with the care takers, other tasks have been altered and their work pressure has been lowered, also because the person that is physical around every night can do other tasks, preparing work for their colleagues.
Conclusions
The case HealthLab Tsaar Peter case has been a good example of how Living Labs can contribute to the procurement of eHealth solutions and applications. A first success can be found in the procurement of a sensoring system, also for other locations.
• Intention: to procure technology that helps to decrease the care gap • Partners: AMSTA, VU, Waag Society, HVA, Amsterdam, AIM, user groups • Objective: creating an environment where new solutions can be piloted and co-developed • Timing: From 2009 to 2011 in creating the Living Lab, now continue
The selection of the approved and innovative solution and the whole process of the project cooperation include the majority of the phases of the so called Pre-commercial procurement of innovation, based on the typical research and innovation life-cycle, transforming an idea into a product/service. Direct benefits are:
• By collaboration relatively low costs before implementation • Very successful adaption of users • Inclusion of education • Joint innovation with industry and thereby pushing private sector investment in innovative
solutions.
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Case 5: Welfare-technology neighbourhood: robotic vacuum cleaner and the
electronic keys: Denmark
The vision behind the project called “Welfare-technology neighbourhood” was to use a neighbourhood in central Copenhagen, Denmark as an Innovation Exploratorium for testing potential welfare-technology in the homecare sector. Ethnographic research identified two areas with distinct potential for testing welfare-technologies. The first one was linked to the elderly people’s wish to keep their home clean and neat. The welfare-technology tested for that purpose was a robotic vacuum cleaner.
The second area was linked to the elderly people’s wish to get quick help in case of an emergency. The welfare-technology tested for that purpose was an electronic key that could give the caregiver immediate access to a citizen’s home in case of an emergency by receiving an entrance code on his/her mobile phone.
Background
Based on an earlier project, the healthcare system in Copenhagen had a wish to create a short term project that could specifically focus on welfare-technology. The underlying rationale for the project was the perceived need for innovation: The health authorities were in a situation where obligations and assignments were getting bigger and the number of ‘warm hands’ to fulfil them were less and less. Consequently, the Innovation Centre Copenhagen (ICPH) and the healthcare administration created the project together and applied for funding.
In Copenhagen, the home healthcare system is organized in ‘neighbourhoods’. The homecare neighbourhoods used to be managed by the healthcare personnel who provided the health care services. This meant that for each patient, the health care personnel would assess the need for help and perform the health services judged to be needed. The advantage with this system was that it was very flexible. The disadvantage was that decisions on what health services were delivered, was based on subjective judgements made by individual members of staff. This made it impossible to create a standardized service level. Today, the healthcare personnel are divided into medical officers and health care workers. The medical officers are often nurses whose task is to assess the need for help based on some established service standards. For instance, at the most, the municipality provides vacuum cleaning every 14th day and in an area no larger than 65m2. The health care workers provide the actual homecare services. The new healthcare model made the health care workers feet that they were no longer able to provide the care and attention they think is necessary. They also complained that with the new model they became busy with practical tasks.
As only practical actions were taken into account in the assessments, the health care workers could no longer spend quality time with the elderly because the elderly could only be assessed to practical care. This also created the phenomenon of comfort-vacuuming.
The intention with the project was, therefore, to use ethnographic studies and workshops to identify areas where new welfare-technologies could take over of some of the practical care functions in order to leave more time for personal care and solicitude.
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The healthcare administration was also interested in the project because it could help to map what different types of citizens lived in the neighbourhood, as well as views on the limits to self-sufficiency in the area of homecare.
The project, partners and selection mechanisms
The “Welfare-technology neighbourhood” project is collaboration between the Copenhagen Municipality - the Department for Health and Care and Innovation Centre Copenhagen (ICPH). The project was based on a wish from the Municipality to impact the development of welfare technology products and services for elderly people. The objective of the project was to use welfare-technology in the municipal homecare in such a way that it would:
Enhance the citizens self-sustainability
Enhance the employee’s working conditions
Municipal time is released
The project was, on purpose, set up as a development project and not as a procurement project.
This happened mainly, because the project managers wanted to be sure that the companies/suppliers would be part of the project to use insights and tests for further development and adaption of their products and not only to secure a large order. Also, the public system was very hesitant to make a pre-commercial procurement contract because it was afraid to make a distortion of competition and, thereby, to break the law. However, at the end of the project, the selected companies expressed a wish for a pre-commercial procurement contract. So, they could ensure their investment in the development project showing the public healthcare system’s willingness to take risk, as well.
Suppliers were selected on the basis of: 1) willingness to invest time and resources in the project; and, 2) willingness to adjust to the public and organizational project setup. But, they were not paid; instead, they were invited into the homes of the elderly citizens to have their products real-life tested.
Interaction and learning
Both the robotic vacuum cleaner and the electronic keys had been used before; however, by June 2008, none of them had been used in the context of elderly people. Initially, the robotic vacuum cleaner was tested in the way it was. The electronic key-system was not changed but incorporated into the caretakers’ mobile phones.
All products and alterations from the project were tested with users such as elderly people and caretakers in real-life situations – as well as in the organizational set-up. Moreover, citizens from the neighbourhood were invited to give their insights on the project at an open meeting. Also, during the project, a number of ethnographers were involved, firstly, to identify the main problem areas and, secondly, to conduct the real-life cases.
The interaction with users, citizens and ethnographers provided a clear priority of the product’s attributes and a significant understanding of the services, systems and situations surrounding the products.
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It was found that the robotic vacuum cleaner needed to have another interface and the keys were simply too small. For instance, there were a number of aha-experiences in which some of the elderly people’s homes are covered with carpets and that could be a challenge for the robotic vacuum cleaner. It was also identified that some features in the vacuum cleaner needed to change. The last point was noteworthy because for all standard robotic vacuum cleaners, it is assumed that people are out of the house when the robot cleans. However, in the ethnographic research, it was noticed that the elderly did not leave their homes when the device was running. Instead, they created some kind of relationship (interaction) with the device (robotic vacuum cleaner) and started to give names to it, for example, “the small helper”. Some elderly even applied a personality to it.
It was also evident that the elderly people would like to have control over the robotic vacuum cleaner; so, it enables them to clean the house by themselves and, consequently, do it in the way they want it. This has led to the idea of a remote control to the robotic vacuum cleaner.
Problems or barriers encountered
During the project, there were mainly two issues: 1) in the beginning there were some logistics problems that were preventing the companies from having access to the elderly people’s homes; it needed some more arrangements; and 2) the group of managers were not involved from the beginning of the project, so, this created resistance and anxiety in the group of employees. This has taught to always involve all levels of management in such projects.
The primary reason why the process took place in the way it did was because there was a strong and narrow vision of the project and a constant focus on quick wins. Furthermore, the outcome of the project have been real-life tests of two welfare-technologies and gain of knowledge on how those can be adjusted to the systems and its needs. And, especially the manufacturer of the robotic vacuum cleaner has benefited from the project because it has changed the supplier’s understanding of the product in this market, and, it has changed their perspective on development – from something thought of as happening in a R&D lab to be something that take place into contact with real-life situations.
A final remark concerns to the decision not to carry out this project as a pre-commercial procurement project. The reason why the authorities were reluctant to make a pre-commercial procurement contract was that they feared this would distort competition and, that they would thereby, potentially risk breaking the law. Another barrier in this case was then a lack of knowledge concerning available methods for public procurement of innovation, especially pre-commercial procurement.
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Case 6: The case of radiotherapy appliances: Italy
One of the first Italian examples of a true pre-commercial procurement call for tender to be set up, the PCP call can be downloaded from the Bolzano Province official website www.bandi-altoadige.it along with all the relevant documents, forms and guidelines for participation.
Available both in Italian and German, the call for tender has been set up according to the specific point of view of the local administrators and shared with the DG Information Society and Media of the European Commission.
This specific PCP call does not exactly match the four stages of a classic PCP scheme, even though such a scheme supplied local officers with important guidance during the development of the call. Indeed, once the public administration have managed to obtain a pre-competitive technical solution, the PCP call for tender will allow for the private company to skip one or two stages and jump directly to the prototype creation stage. In this specific case, the prototype will be tested by the Bolzano Hospital together with the selected private company/ies, in order to get directly to the definition of the prototype itself.
This specific approach has two advantages:
1) Time reduction between definition and needs of the performer on one side, and setting up of the prototype on the other side;
2) Less bureaucracy in project proposal evaluation;
3) More added value given to public buyer’s skills, as these ones will be used in all project planning and prototype set up phases.
To a closer inspection, it looks like as the call was built starting from an RTD approach instead of a pre-competitive one. However, we should bear in mind that the pattern proposed by the European Commission is a flexible one and can thus be adapted to single cases every time in a different way. Indeed, a good project proposal and its implementation should also manifest a favourable cost/benefit ratio. The lack of an expense cap and a clear definition of eligible costs would allow for inexistent and undocumented costs to be funded, thus causing a loss to the public administration.
Legal premises
According to law n. 14 of 13/12/2006, the “Assessorato all’Innovazione” (Councillorship for Innovation) of the Bolzano Province is competent to grant “state aid” contributions and loans to enterprises conducting R&D&I activities and participating in innovation projects. Such a law has been notified to the European Community with Act N466/2007 and has been validated with a letter from Mrs. Neelie Kroes of 18/02/08 – ref. D/299675. Within the framework of this law and its criteria, the “Assessorato all’Innovazione” can also promote collaboration projects between private enterprises and public research units.
The “Assessorato all’Innovazione” – willing to promote the implementation of COM(2007) 799 “Pre-commercial Procurement: Driving innovation to ensure sustainable high quality public services in Europe” – set up a pilot project between a private firm to be selected through a specific call and the Public Health Unit of Bolzano (Comprensorio Sanitario di Bolzano).
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Functional needs analysis
The “Assessorato all’Innovazione” has carried out a research programme on local specific needs and, amongst all the proposals that have been submitted, a particular one called ”Closed Loop”: Advanced automation and management of the clinical risk and trials in Medical Oncological therapy has been selected by the Public Health Unit of Bolzano. This took place in October 2011, and aims at rendering innovation in radiotherapy appliances.
PCP project players
The stakeholders were as follows:
A) Bolzano Province Councillorship for Innovation B) Public Health Unit of Bolzano – Oncologic and Pharmaceutical Units C) A private company to be chosen through a call for proposal A) The role of the “Assessorato all’Innovazione” was to:
To prepare a call for proposal (forms, financial sheets, work package schemes) to choose the private partner cooperating with the Public Health Unit
To establish an evaluation scheme and a call procedure
To evaluate the proposals with a technical committee
To draw a contract to be signed by the private partner and the Public Health Unit
To check periodically the “state of the work” of the project and the eligibility of expenses
To finance 100% of the costs supported by the Public Health Unit of Bolzano and 70 % of those supported by the private company (co-financing for the remaining 30%)
B) The role of the Public Health Unit of Bolzano – Oncologic and Pharmaceutical Units:
Does not contract out any predefined solutions
Exploits internal research and experimentation units
Exploits, for further research activities, the research and innovation budget obtained by royalties on prototype
C) The role of the private company
Covers a variable percentage of risk
Shares future incomes with the public body
Improves its image indirectly thanks to the cooperation with the public body
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Figure 8. The PCP-like process for innovative radiotherapy appliances.
Public Health
Unit of Bolzano
CALL FOR
PROPOSAL
EVALUATION OF
PROPOSALS CONTRACT
FORMALISATION
PREPARATION
OF CONTRACT
PERIODICAL
CHECKS ON THE
PROJECT
Assessorato
all´Innovazione
Provincia di
Bolzano financing
3
4
SHARING ROYALTIES OF
PROTOTYPE
Private Company
FUNCTIONAL NEEDS ANALYSIS
2
1
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Case 7: Stabilising splints for fractured neck of femur : UK NHS/NIC case
In the summer 2009, thirty representatives of front-line staff and end users from the English, Welsh and Scottish Ambulance Service identified a number of important clinical needs within the service. One of those needs was for a splint to immobilise a Fractured Neck of Femur (FNoF). FNoF is a condition that affects mainly the elderly and is often the result of a fall. The condition is very painful for the patient and prognosis is poor, with significant follow-up Health and Social Care costs. Fractured joints are typically stabilised by a splint, but existing splints are too complicated, difficult to fit quickly and often fail to immobilise the hip joint successfully.
Step One - Define the Need
The key representatives of the national Ambulance Services identified the problems like this:
“The existing splint is too complicated to use, there are too many straps, and bits tend to go missing. If all the bits are there and they can get it to fit properly it does little to stabilise the patient over rough terrain or when moving them. If they can’t get it to work in ten seconds they won’t use it, especially in emergencies (known as the 10 Second Rule). There is recognition that getting an elderly person down three flights of stairs in a cluttered house with no working lights is exactly why a better splint is needed, especially when you combine this with the existing carry chair which does little to help the situation.”
They were then asked to consider and complete the phrase ‘Wouldn’t It Be Great If…..’ Here’s what they said:
“Wouldn’t It Be Great If…. we had an easy to use/re-use mechanism for moving patients with a fractured neck of femur which would self regulate/stabilise whilst the patient was in transit and help protect the patient from further injury to an already painful complaint.”
The group went onto identify attributes in four categories:
Features of the innovation. The group identified eighteen design solution attributes. Of these, the priorities included “the splint should be lightweight but with shock absorbing properties, it should have the ability to be deployed over clothing if required and it needs to be x-ray clear.”
Business opportunities. The group identified nine business opportunities. Of these, the priorities included “large numbers of Ambulance Trusts would purchase the splint, the kit could span other areas such as Orthopaedic post-op recovery and budgets for development could be available.”
Research requirements. The group identified eleven research requirements. Of these, the priorities included “early economic assessment would be needed, prior art and the evidence base for adoption”.
Enablers. The group identified 16 enablers. Of these, the priorities included ‘independent device development partners, IP and funding’.
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At the end of the Phase 1 Design, a stage gate design review was held, facilitated by the NIC and attended by the clinical leads. At this stage a group decision was made regarding the most suitable design. This was based on ease of use, patient comfort and manufacturing costs.
Step two – Design the solution
After prioritising the attributes, the NIC ran a competition inviting firms to apply to design and develop the first prototypes. The response from both commercial organisations and individual innovators was high and, from these expressions of interest, the NIC selected two development partners. Front line staff who had been involved in identifying the need were also involved at every subsequent stage. This enabled designers and developers to get immediate and on-going feedback from the end users.
Phase one funding was £45k in total. Having subjected the designs to a detailed stage gate review at the end of this phase, one organisation was selected to progress the design. At this point an award of £80k was given to further the development of the design and this was supplemented by a further £90k to redesign the patient pathway and prepare for ethics and trials approvals.
The use of a phased approach such as this helps to reduce risk for the commissioning authority. For example, if an innovation is not developing as expected, the NIC is able to halt further call-down on cost and time resources using a staged competition approach.
Step three – Develop the opportunity
This phase of work included the assembly of initial prototype models. This enabled clinicians to have a ‘look and feel’ of the product and provide valuable inputs to the prototype design. These prototypes also helped enable key decisions to be made regarding the most suitable design to proceed. The prototyping also helped early stage production costs to be considered in conjunction with further areas of cost reduction.
A key element in the NIC’s process was to encourage open collaboration and spread the work to the most appropriate party. As a result, one of the design houses that had won the contract successfully joined forces with a further external designer. The entire project was managed as an integrated programme of work, using on-line toolsets to share ideas and report on progress. The project work plan was split up into deliverables and underpinned by a strong governance structure. In some cases, additional resources, such as workshops, were supplied by the NIC.
Step four – Demonstrate the benefit
The forth step concerns providing evidence of the benefit of an innovation gathered for instance through clinical trials. Stringent regulatory and ethics approvals are also required as part of clinical trials for Healthcare technology products.
In this case the NIC brokered an agreement for trials between the successful design house and a clinical lead in the NHS. Working with the Chair in Orthopaedics at a local university, the trial also included an assessment of how the device would affect the patient pathways. Autumn 2011, fifteen prototype units began a three-month trial across an NHS Foundation Trust region and the local Ambulance Service.
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Step five – Distribute the product
In spring 2012, the trials programme will conclude. A fully detailed report will be produced to support the trials outcomes and recommendations. Any changes to the design will be considered and incorporated via a disciplined change control process. Once base-lined for manufacturing, tooling, production and distribution networks will then be enabled and initial batch production will commence with delivery into service Early planning of the production programme is key to ensuring the correct manufacturing channels are set up and agreed. This will mean that, as demand increases, the appropriate number of quality-assured products will be available across the NHS.
The most senior member of the English Ambulance Service nationally, Chief Executive of the London Ambulance Service, Peter Bradley, has supported the Ambulance PCP approach from the outset.
In August 2011 he said: “When I was approached by the NIC I was happy to lend support as the need for improved clinical equipment for ambulance crews was self-evident. I was especially drawn by their philosophy of involving the end-user in the design process and was curious to see how things would unfold. So I must say that I’m delighted at the direction the project has taken. It’s great to see front-line ambulance staff from three different ambulance services involved in technology-based projects aimed at improving patient care. So, like everyone else, I’m looking forward to seeing the new products in action!”
Figure 9. An innovative device to stabilise a fractured neck of femur.
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Case 8 : The Healthy Helsinki Living Lab mHealth PPI case
- A case where PCP could have been useful
In the light of the fact that PCP is rather new to many member states, one interesting exercise is to enact how PCP could have been useful if applied in a certain project. Following that line of thought, this section discusses a case that encountered some interaction problems. As will be displayed below, PCP, if applied, could have helped to reduce some of the problems encountered.
Background
The Finnish Healthy Borough Programme, also known as Healthy Helsinki Living Lab (running 2008-2011), is a public-private collaboration project involving the City of Helsinki, the facilitation unit Forum Virium Helsinki, private companies (mainly within the IT and telecom sectors) and NGOs.
The Healthy Borough Programme developed a series of PPI (public-private innovation) sub-projects, including the Mobile Health Programme, which is the focus of this case study. The Mobile Health project aimed at increasing personal responsibility and offering new possibilities for individuals to take care of their health. In addition the target was to generate new innovative digital services and well-being technologies.
The partners
The project was established in one region within the city of Helsinki) by the Helsinki City Administration and Health Services. Later, however, Sports, Education and Social Services Departments have been involved as well. The aim for the public partner was to improve population health in the Helsinki area, and to develop innovative approaches to prevention and health promotion in collaboration with private enterprises and society. The underlying concerns were observations of health inequality, perceived problems in health status and increasing health expenditures. The aim for the private partners was to develop business opportunities particularly in relation to health/welfare and IT/telecom solutions. The role of Forum Virium was to facilitate dialogue between public and private partners in order to identify problem areas and ideas that can be turned into partnership projects. Forum Virium also acted as fund-raising agent for the sub-projects. The most important private companies participating in the sub-projects were Elisa, Logica, Medineuvo, Medixine, Nokia, Palmia and Tieto. Elisa was the private partner in the Mobile Health Project. The public partner views the Programme as a way to develop innovative approaches to public health problems. The private partners in the sub-projects view the partnerships as a way to develop and test products that may be commercially viable. Private third sector representatives see it as a way to get attention to particular issues and to get private and public actors involved in solving such issues. The public partner bears the main financial risk. The financial risk for private partners is the commitment of time and resources in developing solutions which may not be commercially viable.
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The product
The Mobile Health Project has developed and tested a service which captures personal information on exercise habits via mobile phones, and pro-vides feedback on progress and achievements, also via the phone. It serves as a personal trainer and a motivational factor for doing exercise. he main objective was to develop more knowledge regarding motivational patterns and to get a differentiated picture of exercise habits. On the technical side the project developed and installed movement sensors on mo-bile phones, to collect personal information on exercise habits. The information is transmitted to a database. This allows for sophisticated analysis of motivational patterns, and provides a platform for more targeted and differentiated public health interventions.
Project organization
A steering group with public and private partners was established for the programme. The steering group evaluated and selected the most promising projects to be implemented. In the Mobile Health Project, the private firm Elisa has worked with public partners to develop a mobile phone-based system for collecting and communicating personal records on exercise habits and health status. The overall Programme is funded by the City of Helsinki and the Finnish State. Additional funding for sub-projects comes from the EU (FP7 and regional development funds) and from TEKES (the national Finnish funding agency for technology innovation) and SITRA, another national Finnish funding agency. Private partners contributed with time in the main project and development resources in the sub-projects.
Project results
The perceived outcomes for the private partner were as follows. The Mobile Health Project was evaluated by researchers at MIT. The evaluators concluded that the project has created a service which adds value to its users, has a commercial potential and contributes to better population health. The private partners point out that the service has induced more citizens to do exercise, and consequently has had a positive impact on public health indicators such as obesity prevention and overall health. The partners have been considering how to move the application into a commercial setting but no concrete results from this final step in the innovation chain are at this moment foreseen.
The perceived outcome for the public partner can be summarized as follows. The Healthy Borough Programme has established a platform for collaboration and has initiated several promising sub-projects. For the public partners, the Healthy Borough Programme represented a significant potential in achieving the goals of better prevention and health promotion in the area. However, most sub-projects have not shown significant results so far, the exception being, the Mobile Health Project as indicated by the evaluators. The public partner views, however, the creation of an ongoing forum for dialogue and project generation between private firms, voluntary associations and the different public agencies as a major benefit in itself.
Barriers
Both the public and the private partners list the following main barriers:
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Public procurement (competition) rules make the process complicated and slow. It takes considerable time and administrative effort to clarify the judicial aspects. The commercialization phase was not incorporated into the project as such and phased difficulties in subsequent deployment of the developed solution/innovation.
Health sector rules tend to be more complex than in other sectors, be-cause they have to ensure privacy, safety, etc. This leads to relatively high administrative costs when applying for funds and administering the programmes.
The private partner further emphasizes the following barriers:
Different cultures and speed of decision-making in public and private partners. Private partners perceive the public partners as slow and bureaucratic.
Public and private firms do not always speak the same language, or have the same time horizon. Forum Virium has an important role in acting as an interpreter between the private and public partners.
Finally, diverging interests among private firms can create problems in establishing collaboration. This is handled through agreements for each sub-project, which makes management of the project complicated and time-consuming for the public project manager.
Drivers for success
Both the public and the private partner point to a shared commitment as a main driver. Both partners perceive a willingness to enter into dialogue and to understand the needs and opportunities for both public and private actors. Both see a general interest in maintaining a structure for presenting ideas and developing projects. The timing must be right for projects to succeed. There are examples of good ideas that are not taken up because key partners have not yet realized the potential. “Hot topics” create fast tracks for getting project proposals through. It can be an important driver for success to seize the right moment and keep momentum in the project.
Potential
Both the public and the private partners view the potential of the project as significant. This is based on the perception of a strong need for developing innovative solutions to the growing challenges of providing welfare services within a financially constrained environment. In this sense both partners see a “burning platform” for change, which can be used to drive partnership projects. The partners also argue that several sub-projects in the Healthy Borough Programme show promising results. However, the transition from a publicly subsidized project in the development phase to a commercially viable product is difficult. New tools must be developed to facilitate this development. The partners indicate that a structured and stepwise guidance tool that can lead them trough the legal, fundraising and business aspects of the transition would be helpful. National funding programmes through TEKES and SITRA are important as seed money for the individual projects.
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Conclusions and recommendations
This above analysis suggests that PCP process could have been one answer to the challenges identified in the Mobile Health project as described above. The recommendations from this project are as follows:
1. It is very important that the public and private partners have clear agreements on their roles and targets in the project. The agreements must be formalised and written down, yet with some possibility for renegotiation as the project progresses.
2. It is important to have agreements on how to use the product/results once the project has
ended. Ownership of products must be determined in advance, and a (tentative) plan for continuation must be developed at an early stage.
3. It would be helpful to develop systematic tools to facilitate and structure all phases of the
project. From initial brainstorming on ideas, to agreement on specific projects, and to commercial exploitation. The tools must include considerations of the legal framework.
4. It is important to bring the private partners in at an early stage (before projects are
defined) in order to create an open dialogue and exchange of ideas.
5. It is very important to have the end users (third-sector representatives) involved in generating ideas and developing projects.
Preco conclusions: There is identified a need for a systematic tool for the R&D&I process with focus on the different phases and aspects of the process in line with those of a PCP process. Subsequently one could argue that PCP could have worked better and provided better results for all parties involved in comparison to the collaboration method chosen. The identified needs include e.g.:
A thorough early needs assessment including all key parties (companies, end-users & others)
Clear contractual and legal procedures, including the IPR’s and ownership issues
Formal commitments and roles of the parties involved in the process
Focus also on the commercialization phase, i.e. in securing deployment (through commercial procurement) of the new solution/service as a final step in the innovation chain.
This above analysis with its recommendations confirms the general finding that Public-Private Innovation (PPI) models can be used for public-private collaboration and for creating innovation. However, their weakness is often that they do not secure deployment and commercialization – i.e. a business case. Lack of competition and envisaged deployment targets make it also uncertain whether the best and most innovative and cost/efficient solution were created.
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Appendix 2: On alternative Demand systems and R&D procurement models
It is important for member states to view PCP in relation to other means to stimulate innovation and also to
consider to what extent there are other methods that might be useful or even preferred in certain
situations. For that purpose it might be useful to look at the basic rationales for innovation policy in
general, i.e. promoting innovation for the purpose of achieving economic growth. Essentially this builds on
the understanding that by innovating, a firm can present a better product on the market, or produce it
more efficiently than its competitors and thus achieve competitive advantages. In order to stay competitive
in the long run firms must continuously evaluate their activities to seek out possibilities for innovation.
Public agencies on different levels can and may want to support and promote firms’ innovative activities.
This is achieved through “knowledge policies” developed to promote e.g. scientific progress or
development within a specific sector in order ultimately to stimulate innovation. The explicit emphasis on
‘knowledge’ underscores that innovation policy builds on “many different sources of knowledge and that
innovation itself is a learning process” 5.
The scope of the current report excludes a more elaborate discussion on the instruments which e.g.
national governments may include in their innovation policies. In brief, one could however distinguish
between three main categories of innovation policies: environmental, supply-side and demand-side
measures6. Examples of environmental measures are tax allowances for firms engaging in Research and
Development (R & D) or intellectual property laws that give firms monopolistic rights to commercialise a
product developed by a firm. Supply-side measures are typically research infrastructure provided by public
agencies, for example public provision of scientific training, public laboratories and R & D grants. Public
procurement is the central component in the demand-side category 7 8 9. Creating demand for innovation is
the cornerstone for promoting public procurement as an innovation policy instrument. As was mentioned
above this has, however, not been utilised fully.
Viewing PCP is one of many possible policy instruments member states may invoke, underscores the
complementary dimension, i.e. that PCP can be seen as one element to be used in conjunction with other
instruments. One example is the development of master plans, as seen typically on sub-national or
municipality levels. A master plan includes typically a strategic long-term plan while in the same time being
rather concrete in terms of envisaged outcomes. In relation to the master plan PCP becomes an instrument
to implement elements in the master plan. A development project can also consist of a combination of
different kinds of procurement processes serving to allocate consultants and specialist. PCP can also be
used in combination with supply-side measures as well as environmental.
Although PCP has a lot of promising features PCP should not be considered as an any-situation
procurement tool. Procurers should be “aware that PCP is not concerned with the procurement of existing
products or services on the market, but with the R&D phase of a product or service before its (potential)
commercialisation.
5 Lundvall, Bengt-Åke and Borrás, Susana 2005. Science, Technology and Innovation Policy in Fagerberg, Jan, Mowery, David C Nelson Richard (Eds.), The Oxford Handbook of Innovation. Oxford University Press. P. 625. 6 Rothwell, Roy 1981. Pointers to government policies for technical innovation. Futures. June. 7 Braun, E. 1980. Government Policies for the Stimulation of Industrial Innovation Technology Policy Unit, University of Aston in Birmingham. In Rothwell, Roy. Pointers to government policies for technical innovation. Futures. June. 8 Geroski, P. A. 1990. Procurement policy as a tool of industrial policy. International review of applied economics, 4. 2, 182-198. 9 Edler Jakob and Georghiou, Luke 2007. Public procurement and innovation - Resurrecting the demand side. Research Policy, 36, 9, 949-963.
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As such, the PCP is not concerned with quantity production, customisation of existing products or other
commercial development activities.10” Also, even if a procurement project targets innovation, other forms
of public procurement of innovation than PCP can be chosen as the preferred option. Factors such as the
knowledge level held by the procurer and the maturity level of the procured technology may make
traditional forms of public procurement of innovation a more sound choice. This way of thinking has been
applied for some years now by the Flemish Government and implemented by the Flemish Innovation
Agency (IWT). The same goes for the UK NHS National Innovation Centre. These two models are
explained briefly in the next section.
1. Examples of Demand-systems for innovation
Some of the cases described in this Preco report are essentially ad-hoc projects, in the sense that they have started as an idea, and then developed into real projects through non-routine actions within the organisations. Another possibility is that PCP is carried out by organisations dedicated to formulate demand for innovation, carry out public procurement and even sometimes help to commercialise the innovations. This section discusses briefly two examples of such demand systems for innovation.
The Flemish Innovation agency (IWT) model:
What is PoI?
The Flemish Innovation Agency IWT has been one of the first ones in the EU to create a methodology for stimulating demand driven public procurement of innovations. The work resulted in a Flemish manual on procurement of innovation and in proposal for the Government for a pilot scheme on pre-commercial procurement. The Flemish Government approved in July 2008 an Action Plan on Procurement of Innovations. The budget for the pilot scheme amounted EUR 10 million for the first 2 years cases. The PoI pilot programme is an experimental platform. PoI is aiming to provide the policy makers in Flanders and in Europe with concrete experience and best practices, which can be used further when preparing a future long term PCP programme for Europe11.
How does PoI work?
The Flemish model for procurement of innovation is presented below. The model describes the entire process of procurement starting from the political ambitions to the final commercial procurement. The Flemish model is based on two essential building blocks: the master plan and the innovation platform.
10 Lucas, Rebeca and Vulcano, Antonella, 2011. PCP Manual A Practical Guide To Pre-Commercial Procurement. Innovative PROcurement techniques to support the GRowth of competitiveness for public services in EASTern Europe (ProgrEAST). Work Package 2 - Deliverable 2.1,
Contract Nº 248352. 11
Veys, Christophe; Thevissen, Peter. PCP related initiatives in Belgium(Flanders region)
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The master plan has a political nature and is formulated by the different policy domains. The plan analyses socio-economic problems or operations of public services and settles on a vision to be reached. Based on the master plan vision, the concrete needs are defined and opportunities for innovations are found. The master plan forms the input for the innovation platform.
Figure 9. The IWT model of public procurement of innovation
The innovation platform is used as platform for collaboration between procurers, knowledge centres and companies.
The main idea of the innovation platform is to compare the degree of innovativeness of the procurer’s procurement need against the available technical solution in the field. The expected outcome of the innovation platform is an advanced master plan. The master plan includes a decision on the best possible mix of policy instruments suitable for achieving the expected outcome.
If the choice of procurement procedure is pre-commercial procedure, then a call for tender is published nationally and internationally in the European Official Journal TED. The call contains the award criteria. The contract will be awarded to preferably three suppliers, which will in parallel compete with each other.
The procurer negotiates with the supplier among others over the following issues: IPRs, right of use/licensing fee and the price paid for the pre-commercial contract (should respond to market conditions and be proportional to the transferred intellectual property rights). After the PCP process the procurer is not obligated to purchase the developed product
Benefits of PoI
The PoI works as a incentive for the Government to realise its needs and to prepare procurement
The Government gets access to innovative solutions for important socio-economic challenges
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Obtaining efficient communication between demand and supply side
Commitment from demand side for innovative solutions
Government and Public sector can increase their network and work with broad range of companies.
Some examples of PoI projects: Healthcare
Eye screening for young children ICT applications for domiciliary care
Sustainable Buildings’ Low-energy building in social housing, rest homes, educational establishment and national heritage property
The UK NHS National Innovation Centre model: Another example is the NHS National Innovation Centre. The NHS National Innovation Centre (NIC) has been operating in the area of health technology innovation development since September 2006. During this time, the NIC has gained extensive experience in the commissioning of innovation, and this experience has led the NIC to one firm conclusion: there is no one-size-fits-all approach to procuring the development of innovations. Instead, the NIC has found it beneficial to take a flexible, context-specific approach to the
procurement of innovation. A critical starting point for the NIC’s work is the answer to this question: Who identified the need? As discussed in more detail below, the answer to this question takes the NIC down one of two paths, either a Reactive path or Proactive path. And, irrespective of which path is followed, they both end at the same point: the development of technological innovations likely to benefit patients and industry. Reactive approach: If a need and a potential solution are identified by an innovator – and not the NIC - then this sits outside of Pre-Commercial Procurement. The NIC is very interested in capturing these needs and
potential solutions, as it complements the more formal approach used in the NIC’s proactive approach. Scorecard: To support this reactive approach, the NIC built and validated – with venture funders, technology developers, innovators, and others – an online tool called Scorecard. This tool enables innovators to assess the potential for their innovation through a series of 48 questions that consider the concept, its value, and the capability of the innovator to deliver. The Scorecard Tool was launched
on the NIC’s web site in Sept 2006. The vast majority of innovators that approach the NIC are not seeking funding, or only seek a small amount of funding.
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What they often are looking for is contact with other experts with whom they can collaborate, or access to the NHS to conduct clinical trials or gain expert healthcare advice. Proactive: If the NIC, as a commissioning authority, identifies a need and has a requirement that cannot be met by the existing marketplace, then this represents a potential Pre-Commercial Procurement opportunity. This is the proactive approach. The NIC uses a formal process to identify, validate and
rank need, and this is informed from structured „Would it not be Great If... (WIBGI)‟ Workshops involving clinical teams from NHS healthcare settings. During a WIBGI workshop, an expert facilitator works with the clinical team to identify, validate and rank-order their perceived clinical needs. The ranked needs are then considered against published literature, resulting in a formal needs assessment document that is presented to the NIC. This results in three possible alternatives for each ranked need: 1. There is technology already available in the market that can meet the need. In this case
traditional procurement is used.
2. There is no technology already available in the market that can meet the need, but NIC’s horizon scanning activities generates evidence that it likely that there will be soon or that it could be soon if industry where aware of this requirement. In this case, the NIC will not engage in a PCP but will publicise the need in the Statement of Clinical Needs section on the NIC website, thus affording industry the opportunity to address the need in the free market.
2. There is no technology already available in the market that can meet the need, and NIC’s
horizon scanning activities do not generate any evidence to indicate that there will be soon or that it could be soon if industry where aware of this requirement. In this case, the NIC will engage in a PCP via the Competition Tool on the NIC website.
Each competition is run via open, fair and transparent processes using the Competition Tool. For any given competition, the NIC may decide in advance to:
Award one contract, or award several contracts
Issue contract(s) just for one stage: design, prototype development, and small-scale trial; or issue contract(s) to cover all stages.
Own IP and full exploitation rights, or not to own IP but own exploitation rights commensurate with the size of the contract.
As a commissioning authority, the NIC designs a PCP competition for each need with the aim to create conditions where a successful outcome is most likely to happen. As indicated below, the more difficult it is to create a technological solution for a challenge, and the more urgent it is that a solution be created, then the more likely it is that the NIC will design a PCP which gives the NIC, as the commissioning authority, more control over the development of the innovation. The converse is also true.
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2. Public Private Innovation ( PPI ) an alternative method for acquiring innovations
The EU Horizon 2020 strategy brings demand driven innovation and public procurement methods into the center of European R&D&I landscape and actions. In view of these envisaged developments the EU Commissions is currently (Horizon 2020) classifying and naming innovative public procurement methods. The terms used in this context, i.e. PCP and PPI, are not commonly known in all EU countries and are also used in different ways. It is therefore important to clarify the way the PPI term is being used In the EU framework currently and within some Member States such as the the Nordic countries.
EU PPI definition: Public Procurement of Innovative solutions (PPI) has been recently been defined by the European Commission as ( see for example the CIP EIP 2011 call for proposals on PPI) “ the purchase of new or significantly improved goods and / or services, processes, etc. that are new to the public procurer and new in the Internal Market”. In a PPI procurement the contracting authority acts as "launching customer", i.e. as the first customer to acquire newly developed commercially viable end-products for deployment. Where PCP concerns the pre-commercial (R&D phase), PPI concerns the follow-up i.e. the commercialization/deployment phase
PPI definition as used in the Nordic countries: In the Nordic context PPI, “Public Private Innovation”, is a well-established term and commonly used alternative method for acquiring innovations in the pre-commercial R&D&I phase – i.e. not in the post R&D phase as in the EU definition. The use of PPI in the Nordic counties has been also described e.g. in the report: “Strategic use of public-private cooperation in the Nordic region”. (TemaNord 2011:510). While the concept of PPI is not well established, it is clear that PPI type of activities are taking place in most EU Member States. The issue is one of terminology and labeling more than anything else.
This type of PPI practices and cases were encountered in both Preco-project thematic fields – i.e. eEnergy and eHealth while looking for the best practice cases. In fact different types of PPI practices have been the prevailing method between public authorities and private companies to collaborate in the pre-commercial phase until now - and much more common than attempts to undertake PCP so far. The Healthy Helsinki Living lab mHealth case (see case descriptions sections) is an example of PPI where a PCP approach could have worked better.
PPI often proceeds until it is possible to provide the public sector with a new solution. Subsequently, the new solution can be procured through a public tender. PPI may include various types of innovation, including:
- Product or service innovation (for instance, a new digital lock solution in relation to
homecare services).
- Process/system innovation (innovative ways of organizing the production of public services and products).
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There prevails however no guarantee that these PPI projects should eventually render commercial procurement, which is of course a weakness. To some extent this same problem prevails also in PCP. The possibilities for procurers not to proceed to a full commercial procurement, which is a good feature in terms of risk management, may also become problematic, in the sense that the PCP model does not guarantee that commercial procurement actually takes place. If a PCP process does not go through also the commercial step, it would mean that it does not work to create real demand (meaning also deployment) for innovation. The focus on the pre-commercial aspect of an innovation’s life cycle also tends to neglect one aspect that might be as important for successful commercialisation, namely diffusion.
Innovative products once developed elsewhere may be very hard to introduce to an organisation due to endogenous institutional barriers. There are, however, means to deal with for example the diffusion problem. There are different policy and practical level developments currently taking place on EU level aiming at this, including the following:
Joint work on interoperability and common standards
Common needs assessment, pooling of demand locally, nationally, EU-level
Sharing of best practices, information and other type of knowledge sharing & collaboration
PCP practices where IPR’s are left with the company, opening possibilities for the company to further develop the solution for other markets and users.
Box 1.1 PPI defined
A PPI project is a mutual cooperative arrangement between public and private organizations with the overall objective of innovating and developing public welfare solutions. Specific aims of a PPI can be the following:
- To improve framework conditions and increase the quality of public services.
- To create new business opportunities for the businesses involved.
Key elements in a PPI are: Continuous transfer of ideas and knowledge between the parties involved. User involvement in the development of the new solutions.
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3. User-Driven Innovation as a driver for PCP in the Health sector
One central aspect of the innovation is interactive learning and co-creation in different forms. The suppliers need to learn from the procurers and vice versa. Both suppliers and procurers need to learn from the future users as well in order to secure a best possible outcome and acceptance of the innovation developed. The following chapter provides a check list/tool for user-driven innovation. The second part of this chapter shows why and how this tool was used in the Danish Preco cases.
User-Driven Innovation – a check list:
1. User involvement can drive sustainability in eHealth
investment and service provisions: Insights from users can help to create more flexible and better needs adopted innovations. Innovations are also more likely to adjust to the complete care chain/path i.e. to the “larger system” and deliver better return on investment ratio (ROI). End user involvement is especially important in cases where the users play a significant role in the care delivery system and function as real
end users of the new solution. This ensures correct adoption and use of the solution having direct implication to how beneficial the new solution is. Change in user behavior can have a greater impact than investment in new technology alone.
2. Start early, finish late User involvement can be used in all different phases of an innovative PCP process, including at the very beginning of the project i.e. the needs assessment – i.e. once the demand has been established. Users can also be involved in the development and prototyping phase and even during the post -commercial procurement phase i.e. while the new solution is taken into use. Early evaluation and feedback can be useful in regard to all phase of the process. Flexibility and change of direction should be allowed according to this. At the earlier stages user involvement can help to direct the development into right direction and right designs. During the later phases user feedback provides information for corrective action once the solution is in use.
The pre-commercial procurement process: a tool for the complete Innovation chain, which can include the users as co-creators: Pre-R&D&I phase R&D&I phase Post –R&D&I phase 0 phase Development phase Commercial up take
Exploratory phase,
Needs assessment,
Ideas
Planning, development, design
Cost/benefit/risk analysis
Prototype, testing
Deployment,
Supervision, follow up
Commercialization,
Diffusion
What is a Living Lab? A Living Lab is a real-life test and experimentation environment where users and producers co-create innovations. Living Labs have been characterized by the European Commission as Public-Private- People Partnerships (PPPP) for user-driven open innovation. A Living Lab employs four main activities: 1. Co-Creation: co-design by users and producers 2. Exploration: discovering emerging usages, behaviors and market opportunities 3. Experimentation: implementing live scenarios within communities of users 4. Evaluation: assessment of concepts, products and services according to socio- ergonomic, socio-cognitive and socio-economic criteria.
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3. Define your user groups Key user groups have to be clearly defined and sometimes also individually targeted and can include many different stakeholders on many different levels (political, managerial, clinicians or patients), depending of the case in question. E.g. there could even be a need to include politicians in order to have backing and understanding for the eHealth investment. The usual reference groups are not always the best and only ones to be used
4. Actively involve your users in different ways and with different methods/tools Different user groups can be integrated systematically in the co-creation/co-design of new innovation in different ways. Clinicians, patients, family members - are a potential source for innovation. Sometimes it could be useful to introduce even bonuses or other types of incentives in order to change user’s behavior in different ways. E.g. to ensure that “old fashioned clinicians” really make use of a new solution once it is deployed/taken into use..
5. Real-life testing environment needed
One way to integrate the users is through the Living Lab methodology (see definition in the box). Examples of the application of the Living Lab concept in public services in the eHealth sector in Preco cases: 1.HealthLab: Tsaar Peter 2.MobileHealth PPI Healthy Helsinki Living Lab 3.Danish Welfare technology neighborhood 4.the Hospital bed of the future
Companies, in particular SMEs (supply side actors) need real-life testing environments (in hospitals, care centers, homes etc) especially in the prototype and deployment phases. In addition to test beds, financial support for this critical phase in the R&D&I life cycle and activity is also needed.
6. User information
Timely and easily accessible information for users increases their knowledge about and commitment to use the new solution in an appropriate way. Targeted impacts or behavioral transformation are more likely to take place.
The Danish experience with user-driven-innovation Some conclusions derived from Preco cases described in the case studies section: User-driven-innovation makes good sense; 1. As an alternative input to the way public institutions are procuring products in Denmark today.
2. If we look at the characteristics of products, which are mainly procured in the health care sector. The products are often low tech or mature technologies, which needs adjustment to the context of the products, as well as the ‘service system’ surrounding them. Here a user-driven-approach is very suitable, because it is:
a) focused on the individual user (time, place, needs, whishes etc.) b) focused on the whole (system, interactions, services etc.)
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3. While user-Driven-Innovation approach can enable to identify the effect needed (for instance in the area of welfare technology) and invite tenders for this.
4. As a way to overcome some of the present barriers for pre-commercial procurement identified in relation to the procurement departments.
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